Methods and apparatuses for graphically indicating station efficiency and pseudo-dynamic error vector magnitude information for a network of wireless stations

ABSTRACT

Methods and apparatuses providing a visual metric of the efficiency of a network of devices communicating through a wireless access point (AP). These apparatuses and methods may also determine and display pseudo-dynamic error vector magnitude (EVM) information for a network of wireless stations, including displaying a pseudo-dynamic constellation diagrams using EVM information. These methods and apparatuses may transmit a plurality of sounding packets from each of one or more radio devices different modulation types (e.g., BPSK, QPSK, 16QAM, 64QAM, 256QAM and 1024QAM), and receiving at least some of the sounding packets at a second radio device (e.g., an access point) and determining EVM information from the received sounding packets, and displaying (or providing for display) a constellation diagram including pseudo-dynamic EVM information that is a constrained approximation of actual EVM information.

CROSS REFERENCE TO RELATED APPLICATIONS

This patent application claims priority to U.S. Provisional PatentApplication No. 62/044,298, filed on Aug. 31, 2014, and titled “METHODSAND APPARATUSES FOR MONITORING NETWORK HEALTH”; U.S. Provisional PatentApplication No. 62/085,218, filed on Nov. 26, 2014, and titled “METHODSAND APPARATUSES FOR MONITORING NETWORK HEALTH”; and U.S. ProvisionalPatent Application No. 62/104,669, filed on Jan. 16, 2015, titled“METHODS AND APPARATUSES FOR MONITORING AND IMPROVING NETWORK HEALTH.”Each of these provisional patent applications is herein incorporated byreference in its entirety.

INCORPORATION BY REFERENCE

All publications and patent applications mentioned in this specificationare herein incorporated by reference in their entirety to the sameextent as if each individual publication or patent application wasspecifically and individually indicated to be incorporated by reference.

BACKGROUND

In establishing communications networks it is often difficult to managethe demands on the network made by various stations, particularly whenthe individual stations may have different usage and operationalparameters. For example, a wireless network may be established e.g., bya wireless Internet service provider (WISP), that services multipleindependent stations, e.g., customer provided equipment (CPE).Individual stations may make demand the bandwidth of the network towhich the station connects at different times and intensities. Further,individual stations may be capable of operating at different ratesbecause of structural limitations (e.g., hardware, software, firmware ofthe station) or because of geographic limitations (e.g., strength ofconnection to the network access point(s)).

Although in general, the demands on networks, from devices includingmobile devices, such as smart phones and tablets, have increased withincreasing prevalence in recent years, networks are becoming increasingstressed. Further, the availability of multimedia streaming (e.g.,video, sound, data) over these same networks has become more common.Given the fast advance in mobile computing power and far-reachingwireless Internet access, more and more users view streamed videos ontheir mobile devices. The detection of network congestion has becomeincreasingly important for network operators attempting to maximize userexperience on the network. Even as network operators are ever increasingthe capacity of their networks, the demand for bandwidth is growing atan even faster pace. Managing network growth and dealing with congestionin the infrastructure is particularly important because of the high costof licensed radio spectrum and limitations of radio access network (RAN)equipment utilized by wireless mobile networks.

Network elements may be able to provide operators a view into thecurrent state of traffic in their network, but they do not provideoverall diagnostic health indicators in a manner that could readilyallow a network operator to identify and potentially address potential(or actual) problems with the network, including any elasticity andcapability in the network, as well as rapidly and intuitively indicatinghow various stations are influencing the network by at the current timeand historically. Such indicators of network health would be importantfor improving and enhancing a network's ability to deliver data in areliable and sustainable fashion. For example, a minimum data rate maybe required to prevent stalling and re-buffering during the streaming ofmultimedia content to stations in a network; ensuring sufficientbandwidth to all (or a majority of) stations/users is important toquality of experience. Typically, multimedia content providers aresufficiently equipped to deliver multimedia content at levels far beyondthe capabilities of wireless infrastructure. Hence, the burden falls onwireless service providers to implement network data optimization toease the traffic burden and maximize the experience of each and everyuser on the network. Currently, only limited tools are available, whichmay not provide sufficient information (and in an easily digestibleform) to properly monitor a network.

For example, one tool useful for understanding the health of a networkis the constellation diagram. A constellation diagram is generally arepresentation of a signal modulated by a digital modulation scheme suchas quadrature amplitude modulation or phase-shift keying. It displaysthe signal as a two-dimensional scatter diagram in the complex plane atsymbol sampling instants. In a more abstract sense, it represents thepossible symbols that may be selected by a given modulation scheme aspoints in the complex plane. Measured constellation diagrams can be usedto recognize the type of interference and distortion in a signal.Constellation diagrams may be generated by measuring the error vectormagnitude (EVM) of a signal, which indicates the deviation of the signalfrom the ideal.

Unfortunately, in practice, even with increasingly fast processorsassociated with wireless devices (including access points), generationof an action constellation diagram, e.g., using actual measured EVMinformation, is time consuming, and may require the addition ofmonitoring components which is impractical and expensive. In particular,the real-time or near-real time display of EVM information (or evenreasonably approximate EVM information) would be greatly beneficial.

Further, although many wireless networks operating through an accesspoint are capable of switching channels, currentchannel-selection/switching techniques are not optimal, and, if theyautomatically switch channels at all, select the new channel based onthe immediate needs, without optimizing at all, or without optimizingbased on the likely ongoing needs of the network. Tools such as thosedescribed above may be used to optimize an access point and thus anetwork (or more than one network) communicating or through the accesspoint. For example, it would be beneficial to optimize the choice of thefrequency channel (and/or the channel bandwidth) for a network. Inparticular, it would be beneficial to optimize a frequency channel for anetwork based on both the operation and/or needs of all or a subset ofclient devices (e.g., the biggest users, highest priority users, etc.)as well as the actual and/or historical state of the frequency spectrumsurrounding the client (and AP) devices. It would also be beneficial toautomatically select an optimal channel and/or bandwidth.

Described herein are apparatuses, including devices and systems (e.g.,tools) and methods, for monitoring, interpreting, and improving theoverall health of a network that may address some or all of the problemsaddressed above.

SUMMARY OF THE DISCLOSURE

In general, described herein are methods and apparatuses, includingdevices, systems, tools, etc. which may include software, firmwareand/or hardware, for providing metrics of a network, and in particular,the efficiency of communication between networked devices, includingdevices networked through a wireless access point. For example,described herein are methods and apparatuses for displaying an indicatorof the efficiency and average airtime of all or a subset of stationscommunicating with an access point. Also described herein are methodsand apparatuses that determine and display error vector magnitude (EVM)information for a network of wireless stations, including displayingconstellation diagrams using EVM (or approximated EVM) information. Thisinformation may be displayed in a dynamic or pseudo-dynamic manner. Alsodescribed herein are methods and apparatuses for optimization of channelselection for an access point of a wireless network, including automaticoptimization of the wireless network. Channels selection may beoptimized by usage data and historical frequency spectral information.

For example, described herein are methods and apparatuses providing avisual metric of the efficiency of a network of devices communicatingthrough a wireless access point (AP). These methods and apparatuses maydisplay a graphical indicator of the efficiency and average airtime ofall or a subset of stations communicating with an AP by time divisionmultiple access (TDMA). An access point or a method of operating anaccess point, may be configured to determine a set of n stations havinghigher usage values compared to all of the stations communicating withthe access point, determine a station efficiency and an average airtimefor each of the n stations in the set, and to graphically display anindicator of the station efficiency, average airtime and an identity foreach of the n stations in the set in order of station efficiency.

As used herein an access point (AP) may be a wireless access point is adevice that allows wireless devices to connect to a wired network usingWi-Fi, or related standards. The AP may connect to a router (via a wirednetwork) as a standalone device, but it may also be an integralcomponent of the router itself.

A client device is typically a device having wireless capability thatmay communicate with an access point. The client device may includecustomer provided equipment (CPE). A client device may also include, andmay be referred to as a wireless device. A client device may be aterminal and/or equipment that connects with a wireless network through,e.g., an access point.

Described herein are methods and systems for monitoring wirelessnetworks, and particularly for determining the effectiveness of one ormore access point (AP) of a wireless network and/or any client devicescommunicating with the AP, and presenting information in a quick,graphical manner that allows intuitive understanding of the efficiencyof the network based on a number (e.g., 5, 6, 7, 8, 9, 10, 1, 12, 13,14, 15, 16, 17, 18, 19, 20, 30, 40, 50, 60, 70, 80, 90, 100, 200, 300,400, etc.) of stations that communicate with the AP.

For example, described herein are method of monitoring and presentingthe health of a wireless network, the method comprising: determining,for an AP, a predetermined number, n, of stations having the highestusage values from all of the stations communicating with the accesspoint, within a predetermined time interval; determining a stationefficiency for each of the n stations; determining an average airtimefor each of the n stations; and graphically displaying an indicator ofthe station efficiency, average airtime and an identity for each of then stations arranged with the n stations in descending order of stationefficiency.

Also described are methods of graphically displaying an indicator of theefficiency of an access point using only a limited number of thestations communicating with the access point, the method comprising:determining, for the access point, a predetermined number, n, ofstations having the highest usage values from all of the stationscommunicating with the access point, within a predetermined timeinterval; determining a station efficiency for each of the n stations;determining an average airtime for each of the n stations; andgraphically displaying an indicator of the efficiency of the accesspoint using the station efficiency and average airtime for each of the nstations.

Any of the methods herein may also include displaying an indicator ofthe efficiency of the access point using the indicator of the stationefficiency and average airtime for each of the n stations. For example,an overall area displayed, or a fraction of the area displayed, in thegraphical representation may reflect the efficiency of the network. Forexample, graphically displaying the indicator of the efficiency of theaccess point may include graphically displaying an indicator of thestation efficiency, average airtime and an identifier for each of the nstations arranged with the n stations in descending order of stationefficiency. The identifier may generally or uniquely identify thestation in the network (e.g., by name, code, alphanumeric,position/location identifier, etc.). This may allow the network operatorto act one or more specific stations to enhance performance of thenetwork.

In any of these methods, determining the predetermine number of stationsmay include creating a sorted list by determining for each stationcommunicating with the access within the predetermined time interval theusage value and the total isolated capacity, sorting the stations byhighest usage value on top and within usage index by lowest isolatedcapacity and selecting the top n stations from the sorted list.

The predetermined time interval may be any appropriate time period,e.g., 2 hours, 4 hours, 8 hours, 12 hours, 18 hours, 24 hours, 36 hours,48 hours, 3 days, 4 days, 5 days, 6 days, 7 days, 2 weeks, 3 weeks, 4weeks, 5 weeks, 2 months, 3 months, 4 months, 5 months, 6 months, etc.

Any of these methods may be configured to select any appropriate numberof the top stations as the predetermined number of stations. Forexample, the predetermined number, n, nay be 5, 6, 7, 8, 9, 10, 11, 12,13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, etc. In somevariations n is limited to 10.

Any of these methods may also include determining for each stationcommunicating with the access point within the predetermined timeinterval the usage value, wherein the usage value for a station iscalculated from the active airtime for that station and a period ofactivity for that station.

In general, graphically displaying may include displaying a figure,picture, chart, graph, or the like that include the sorted and scaledstation efficiency and active time. The graphical display may beinteractive, e.g., allowing the presentation of additional informationwhen selecting or moving over each parts of the display (e.g., showingthe identity or other station-specific information, etc.). Graphicallydisplaying may comprise scaling each indicator of the station efficiencyby a maximum capacity for the access point. Graphically displaying mayinclude scaling each indicator of station average airtime by the sum ofall of the station average airtimes for the n stations. Graphicallydisplaying an indicator of the station efficiency, average airtime andidentify for each of the n stations may include displaying a bar graphwherein each station forms a bar having a height equivalent to thestation efficiency for the station and a width equivalent to the averageairtime for the station.

Any of these methods may also include periodically repeating thedetermining and displaying steps at a predetermined sampling interval.The sampling interval may be the “heartbeat” rate for the network (inwhich status information is transmitted components of the network, e.g.,to a cloud application) The sampling interval may be between 1 secondand 1 day or more (e.g., 10 sec, 15 sec, 30 sec, 1 min, 5 min, 10 min,15 min, 30 min, etc.). In some variations the predetermined samplinginterval is 30 seconds.

Any of these methods may also include periodically transmitting fromeach station to the access point a total packet transmit duration and aduration of failed attempts. A method may include determining a transmitpacket air time and error rate accounting for each station.

In any of these methods, a total air time may be determined by:determining for each station a downlink time and packet error rate fromthe station to the access point; and determining for each station anuplink time and a packet error rate from the access point to thestation.

The methods described herein may also include remotely accessing, usinga processor that is remote to the access point, the usage values for allof the stations communicating with the access point.

Also described herein are systems for monitoring a network (e.g., one ormore access point communicating with a plurality of different stations).Any of these systems may be configured as a non-transitorycomputer-readable storage medium storing a set of instructions capableof being executed by a processor, that when executed by the processorcauses the processor to perform steps including any of the method stepsdescribed above. The processor may be general-purpose processor, or itmay be a custom and/or dedicated processor. A dedicated processor may befaster and more efficient.

For example, described herein are non-transitory computer-readablestorage medium storing a set of instructions capable of being executedby a processor, that when executed by the processor causes the processorto: determine, for an access point, a predetermined number, n, ofstations having the highest usage values from all of the stationscommunicating with the access point, within a predetermined timeinterval; determine a station efficiency for each of the n stations;determine an average airtime for each of the n stations; and cause to begraphical displayed, an indicator of the station efficiency, averageairtime and an identity (identifier) for each of the n stations arrangedwith the n stations in descending order of station efficiency.

A non-transitory computer-readable storage medium storing a set ofinstructions capable of being executed by a processor, that whenexecuted by the processor may cause the processor to: determine, for theaccess point, a predetermined number, n, of stations having the highestusage values from all of the stations communicating with the accesspoint, within a predetermined time interval; determine a stationefficiency for each of the n stations; determine an average airtime foreach of the n stations; and cause to be graphically displayed, anindicator of the efficiency of the access point using the stationefficiency and average airtime for each of the n stations.

For example, a method of monitoring and presenting the health of awireless network may provide a ranked indicator of station efficiency,and may include: determining, for an access point, a set of apredetermined number, n, of stations having higher usage values comparedto all of the stations communicating with the access point, within apredetermined time interval; determining a station efficiency for eachof the n stations in the set; determining an average airtime for each ofthe n stations in the set; and graphically displaying an indicator ofthe station efficiency, average airtime and an identity for each of then stations in the set arranged with the n stations in descending orderof station efficiency.

Any of these methods may be configured as methods of graphicallydisplaying an indicator of the efficiency of an access pointcommunicating with a plurality of stations, using only a limited numberof the stations by providing a ranked indicator of station efficiency,and may include: determining, for the access point, a set of apredetermined number, n, of stations having higher usage values comparedto all of the stations communicating with the access point, within apredetermined time interval; determining a station efficiency for eachof the n stations in the set; determining an average airtime for each ofthe n stations in the set; and graphically displaying an indicator ofthe efficiency of the access point using the station efficiency andaverage airtime for each of the n stations in the set.

As mentioned, any of the methods described herein may include displayingan indicator of the efficiency of the AP using the indicator of thestation efficiency and average airtime for each of the n stations in theset. Graphically displaying the indicator of the efficiency of theaccess point may include graphically displaying an indicator of thestation efficiency, average airtime and an identity for each of the nstations in the set arranged with the n stations. This may be displayedin either ascending or descending order of station efficiency.

Determining the set of stations may include creating a sorted list bydetermining for each station communicating with the access point withinthe predetermined time interval the usage value and a total isolatedcapacity, sorting the stations by highest usage value on top and withinusage index by lowest isolated capacity and selecting the top n stationsfrom the sorted list.

Any appropriate predetermined time interval may be used, for example, 24hours, 48 hours, 3 days, 4 days, 5 days, 6 days, 7 days, 8 days, etc.

As mentioned above, the predetermined number, n, may be between anyappropriate number of stations representing a sub-set of the totalnumber of stations communicating with the access point. For example, nmay be between about 5 and about 50, e.g., between about 10 and about40, between about 10 and about 30, between about 15 and about 25, about20, etc.

Any of the methods described herein may include determining for eachstation communicating with the access within the predetermined timeinterval the usage value, wherein the usage value for a station iscalculated from the active airtime for that station and a period ofactivity for that station.

When graphically displaying any of the information described herein(including station efficiency and average airtime), the method, or anapparatus configured to perform the method, may scale the information.For example, when graphically displaying the station efficiency, eachindicator of the station efficiency may be scaled by a maximum capacityfor the access point. Graphically displaying may include scaling eachindicator of station average airtime by the sum of all of the stationaverage airtimes for the set of n stations.

As mentioned, any appropriate graphical display may be used, includingcharts, graphs, and the like. For example, graphically displaying anindicator of the station efficiency, average airtime and identify foreach of the n stations in the set may include displaying a bar graphwherein each station forms a bar having a height equivalent to thestation efficiency for that station and a width equivalent to theaverage airtime for that station.

Any of the methods described herein may include repeating any of thesteps, including repeating the determining and displaying steps. Forexample, any of the methods may include periodically repeating thedetermining and displaying steps at a predetermined sampling interval.Any predetermined sampling interval may be used, including, e.g., 0.5seconds, 1 second, 2 seconds, 5 seconds, 10 seconds, 15 seconds, 30seconds, 45 seconds, 1 minute, 2 minutes, 3 minutes, 4 minutes, 5minutes, 10 minutes, 15 minutes, etc.

Any of the methods described herein may include periodicallytransmitting from each station to the access point a total packettransmit duration and a duration of failed attempts. Any of thesemethods may include determining for each station in the set a transmitpacket air time and error rate accounting.

As mentioned above, a total air time may be determined by: determiningfor each station a downlink time and packet error rate from the stationto the access point, and determining for each station an uplink time anda packet error rate from the access point to the station.

In any of the methods described herein, the usage values may be assessedremotely, using a processor that is remote to the access point, for oneor more (e.g., all) of the stations communicating with the access point.

An apparatus, and particularly an access point, may be configured toperform any of the methods described herein. The AP may be remotelyaccessed (e.g., by a user) to provide any of the information, graphicaldisplays, and/or the ability to make modifications to the system (e.g.,setting the channel and/or bandwidth, etc.). A user interface may beprovided. The user interface may be provided by the access point (e.g.,when accessing the information); information presented by the userinterface may be provided by the access point. In some variations, theapparatus (e.g., user interface) may include and be configured topresent the user with the user interface, for example, when accessingthe AP remotely or locally. The user interface (including graphicaldisplays) may be displayed on a user's laptop computer, desktopcomputer, smartphone, etc.). Any of the apparatuses described herein maygenerally include a controller and/or processor (or a controller thatincludes a processor) that is configured to perform any of the functionsdescribed herein. These apparatuses may be configured as access points,which may include radio circuitry (transmitter/receiver circuitry), andan antenna. The controller may include a memory, timer, comparator, andthe like. These access point apparatuses may generally be configured sothat the controller operates the radio (and antenna) to receive andtransmit to/from one or more stations as described herein. In general,any of these apparatuses may include non-transitory computer-readablestorage media storing instructions that are executed by the processor(e.g., controller) to perform the functions described.

For example, described herein are non-transitory computer-readablestorage media storing a set (or sets) of instructions capable of beingexecuted by a processor, that when executed by the processor causes theprocessor to: determine, for an access point, a set of a predeterminednumber, n, of stations having higher usage values compared to all of thestations communicating with the access point, within a predeterminedtime interval; determine a station efficiency for each of the n stationsin the set; determine an average airtime for each of the n stations inthe set; and graphically displaying an indicator of the stationefficiency, average airtime and an identity for each of the n stationsin the set arranged with the n stations in descending order of stationefficiency

For example, described herein are a non-transitory computer-readablestorage medium storing a set of instructions capable of being executedby a processor, that when executed by the processor causes the processorto: determine, for the access point, a set of a predetermined number, n,of stations having higher usage values compared to all of the stationscommunicating with the access point, within a predetermined timeinterval; determine a station efficiency for each of the n stations inthe set; determine an average airtime for each of the n stations in theset; and graphically display an indicator of the efficiency of theaccess point using the station efficiency and average airtime for eachof the n stations in the set.

In general, also described herein are graphical methods of visuallydisplaying and interpreting the performance of a network, access point,and/or clients (e.g., wireless radio antenna systems) by displaying oneor both (e.g., side-by-side) histograms and constellation diagrams ofthe error vector magnitude (“EVM”), which may also referred to asreceive constellation error or (RCE).

For example, described herein are methods and apparatuses configured todetermine and display error vector magnitude (EVM) information for anetwork of wireless stations, including displaying a pseudo-dynamicconstellation diagrams using EVM information. For example, describedherein are methods and apparatuses for monitoring a wireless network bytransmitting a plurality of sounding packets from each of one or moreradio devices different modulation types (e.g., BPSK, QPSK, 16QAM,64QAM, 256QAM and 1024QAM), and receiving at least some of the soundingpackets at a second radio device (e.g., an access point) and determiningEVM information from the received sounding packets, and displaying (orproviding for display) a constellation diagram and/or a histogram basedon the EVM information. In particular, these apparatuses and methods maygenerate and display pseudo-dynamic EVM information that is aconstrained approximation of actual EVM information. The modulation typefor the constellation diagram may be changed based on availablemodulation types, or it may be automatically selected based on anoptimal modulation type.

As used herein a pseudo-dynamic display, e.g., of a constellationdiagram, may refer to a display in which the values and/or positions(corresponding to values) being displayed are based on pseudo-EVM data,which is not true or actually measured, but may be randomly generatedwithin a constrained range of an estimated value. Thus, although thedisplay appears to update dynamically, the values displayed illustratethe range, but not the actual value.

In general, the methods and apparatuses described herein include thedisplays (e.g., user interfaces) for monitoring a wireless network (or asingle link of a wireless network), including constellation diagrams.These methods, and apparatuses configured to perform them, may generallyuse a plurality of sounding packets that are transmitted between devices(e.g., between the access point and each of the stations communicatingwith the access point) where the sounding packets within a set ofsounding packets transmitted each reference a particular modulationtypes (and multiple modulation types are represented) and aretransmitted at the referenced modulation type. Examples of modulationtypes may include: BPSK, QPSK, 16QAM, 64QAM, 256QAM and 1024QAM.Additional information about the link may also be included in thesounding packet, as described in more detail below. EVM information maybe determined based on the received sounding packet (including thequality of the received packet and/or information encoded in thereceived packet which may include information about packets transmittedby the AP receiving the sounding packets).

For example, described herein are methods of monitoring a wirelessnetwork that may include: transmitting a plurality of sounding packetsfrom a first radio device, wherein each of the plurality of soundingpackets are transmitted in a different modulation type; receiving atleast some of the plurality of sounding packets at a second radiodevice; determining error vector magnitude information from the receivedat least some of the plurality of sounding packets; and displaying oneor both of a constellation diagram and a histogram based on the errorvector magnitude information.

A method of monitoring a wireless network may include: establishing linkbetween a first radio device and a second radio device; periodicallytransmitting a plurality of sounding packets from the first radiodevice, wherein each of the plurality of sounding packets aretransmitted in a different modulation type; receiving at least some ofthe plurality of sounding packets at the second radio device;determining error vector magnitude information from the received atleast some of the plurality of sounding packets; aggregating thedetermined error vector magnitude for a predetermined period of time;and displaying one or both of a constellation diagram and a histogrambased on the aggregated error vector magnitude information.

A method of monitoring a wireless network may include: transmitting aplurality of sounding packets from a first radio device, wherein each ofthe plurality of sounding packets are transmitted in a differentmodulation type; receiving at least some of the plurality of soundingpackets at a second radio device; determining error vector magnitude(EVM) information from the received at least some of the plurality ofsounding packets; and displaying an animated constellation diagram bygenerating pseudo-EVM data points based on the EVM information, whereinthe pseudo-EVM data points are determined within a standard deviation ofthe error vector magnitude information.

Any of these methods may include transmitting the plurality of soundingpackets from the first radio device by transmitting three or moresounding packets, wherein each of the three or more sounding packets aretransmitted in a different modulation type. For example, transmittingthe plurality of sounding packets from the first radio device mayinclude transmitting three or more sounding packets, wherein each of thethree or more sounding packets are transmitted in a different modulationtype selected from the group consisting of: BPSK, QPSK, 16QAM, 64QAM,256QAM and 1024QAM (ranked from lowest to highest). In any of thesemethods (or apparatuses configured to perform all or some of thesemethods), transmitting may include repeatedly and sequentiallytransmitting sounding patents in each of three of more differentmodulation types.

As mentioned, each sounding packet may encode error vector magnitude(EVM) information.

Error vector magnitude (EVM) information may be determined from thereceived sounding packets by, for example, selecting the error vectormagnitude information from the received sounding packets based on thehighest-order modulation type received by the second radio device.

Displaying one or both of the constellation diagram and the histogrambased on the error vector magnitude information may include displayingboth the constellation diagram and the histogram. Displaying an animatedconstellation diagram by generating pseudo-EVM data points may includeupdating the constellation diagram by generating new pseudo-EVM datapoints based on the EVM information before determining new EVMinformation from received at least some of the plurality of soundingpackets.

Transmitting the plurality of sounding packets from the first radiodevice may include transmitting three sounding patents comprising BPSK,16QAM, and 256QAM (though any other and/or additional modulation typesmay be used).

Displaying one or both of the constellation diagram and the histogrammay include displaying an animated constellation diagram by plottingpseudo-EVM data points based on the error vector magnitude information,wherein the pseudo-EVM data points are determined within a standarddeviation of the error vector magnitude information determined asdescribed herein.

Any of the methods described herein may also include selecting themodulation type of the constellation diagram based on the receivedsounding packets. As mentioned, the constellation diagram may bedisplayed as the highest modulation type that was successfully and/orreliably transmitted.

Also described herein are wireless devices configured to optimizemodulation type when wirelessly communicating. As mentioned above, theseapparatuses may be access points configured to estimate EVM (and/orpseudo-EVM) information and provide for the display of this information,e.g., as a constellation diagram. For example, a device may include: awireless radio; an antenna; and a controller coupled to the wirelessradio and configured to receive a plurality of sounding packets whereinat least some of the sounding packets have been modulated with differentmodulation types, wherein the controller is configured to determineerror vector magnitude (EVM) information from the received at least someof the plurality of sounding packets; and an output coupled to thecontroller and configured to output one or both of a constellationdiagram and a histogram based on the error vector magnitude information.

The controller may be configured to transmit a second plurality ofsounding packets from the wireless radio and antenna, wherein at leastsome of the sounding packets of the second plurality of sounding packetsare transmitted in different modulation types (e.g., transmitted a threeor more modulation types where each sounding packet indicates/encodesthe type of modulation that it is being transmitted at). For example,the controller may be configured to receive at least three or moresounding packets, wherein each of the three or more sounding packets aretransmitted in a different modulation type. A controller may beconfigured to receive a plurality of sounding packets, wherein thesounding packets are transmitted in different modulation types selectedfrom the group consisting of: BPSK, QPSK, 16QAM, 64QAM, 256QAM and1024QAM. The controller may be configured to receive the plurality ofsounding packets that are repeatedly and sequentially transmitted ineach of three of more different modulation types.

In general, the controller may be configured to receive sounding packetsthat encode EVM information, including information about packets thatthe controller previously transmitted that were received by the clientdevice. Thus an apparatus may be a client device that includes awireless radio, antenna, and a controller (e.g., processor) that alsoreceives sounding packets (transmitted by the AP), and transmitssounding packets back to the AP and encodes information about thesounding packets (e.g., EVM information) that is derived from thereceived sounding packets (sounding packets from the AP).

Thus, in any of these devices and methods, the controller may beconfigured to determine EVM information encoded in the receivedplurality of sounding packets and/or based on the quality of thesounding packets. For example, the controller may be configured todetermine EVM information by selecting EVM information from the receivedsounding packets based on the highest-order modulation type received bythe device.

In general, the controller may be configured to output EVM informationabout one or more links (client devices). For example, the controllermay be configured to output both a constellation diagram and ahistogram.

A controller may be configured to output an animated constellationdiagram by generating pseudo-EVM data points and updating theconstellation diagram by generating new pseudo-EVM data points based onthe EVM information before determining new EVM information from receivedat least some of the plurality of sounding packets. Thus, as mentionedabove, pseudo-EVM data points may be generated (e.g., randomlygenerated) within a predetermined range based on the already-determinedand/or approximated EVM data, giving the appearance of a dynamicdisplay. For example, the output may be configured to output an animatedconstellation diagram by providing pseudo-EVM data points based on theerror vector magnitude information, wherein the pseudo-EVM data pointsare within a standard deviation of the error vector magnitudeinformation.

Described herein are method for optimizing and/or automatic selection ofthe channel frequency and/or bandwidth of a network, e.g., of an accesspoint and its client devices. Also described herein are apparatusesincluding devices, and in particular access point devices, that areconfigured to optimize the channel frequency and/or bandwidth (and insome cases automatically change the channel frequency and/or bandwidth)based on historical frequency spectral information going back at least24 hours, but in some cases further than 48 hours, 3 days, 4 days, 5days, 6 days, 7 days, 8 days, 9 days, etc., as well as usage data (e.g.,signal strength) specific to all or some of the device(s) forming thenetwork. The optimization may also account for device-specific usageparameters based on applied priority (e.g., a ranking or grading appliedby the user or another party). This allows the apparatus to moreeffectively optimize the channel frequency (and/or bandwidth) based onthe actual or expected needs of the network.

For example, described herein are methods and apparatuses foroptimization of channel selection for an access point of a wirelessnetwork, including automatic optimization and channel selection for thewireless network. Channels selection may be optimized by usage data andhistorical frequency spectral information from all or a sub-set ofwireless devices (e.g., stations) in the wireless network. For example,described herein are wireless access points and methods of using themfor optimizing channel selection by collecting historical (e.g., 24hours or longer) frequency spectral information and usage data (e.g.,signal strength) devices wirelessly connected to the access point, anddetermining a list of frequencies having high spectral efficiencies, inbit per second per a channel width.

For example, a method of optimizing channel selection for an accesspoint wirelessly connected to one or more other devices may includecollecting, in the access point, 24 hours or longer worth of frequencyspectral information; collecting, in the access point, usage data forthe one or more other devices wirelessly connected to the access point;and determining a ranking of spectral efficiency, in bit per second pera channel width, for a plurality of frequency channels based on thecollected frequency spectral information and the usage data.

A method of optimizing channel selection for an access point wirelesslyconnected to one or more other devices may include: collecting, in theaccess point, 24 hours or longer worth of frequency spectralinformation; collecting, in the access point, usage data for the one ormore other devices wirelessly connected to the access point; determininga ranking of spectral efficiency, in bit per second per a channel width,for a plurality of frequency channels based on the collected frequencyspectral information and the usage data; and automatically selecting thechannel for the access point based on the determined ranking.

Any of these methods may include automatically selecting a channel forthe access point based on the determined ranking.

In addition, any of these methods may include displaying the ranking offrequency channels based on the collected frequency spectralinformation. Displaying the ranking may include displaying some numberof the top-ranked channels (e.g., the top one, the top two, the topthree, the top four, etc.); the actual rankings/score does not need tobe displayed. For example, any of the methods may include displaying oneor more of a top-ranked frequency channel based on the determining aranking.

The methods for optimizing may also include allowing a user tographically select a frequency and displaying a spectral efficiency forthe selected frequency based on the collected frequency spectralinformation and usage data. Spectral efficiency may also be calledspectrum efficiency or bandwidth efficiency and may refer to theinformation rate that can be transmitted over a given bandwidth in aspecific communication system.

In any of the methods (and apparatuses configured to implement thesemethods) the user may manually set the channel width (bandwidth) and/orone or more default channel widths may be assumed; for example, multiplechannel widths may be used and displayed. In some variations the methodand/or apparatus may automatically determine a channel width based onthe network, such as the use data for the network component devicesand/or the properties of the AP and/or client devices (e.g., the maximumand/or preferred bandwidth for the network devices), etc.

In general, the AP and/or all or some of the client devices may beconfigured to detect spectral information. As described in greaterdetail below, the AP and/or all or some of the client devices mayinclude a receiver configured as a spectrum analyzer, which may operatein parallel with the wireless radio receiver/transmitter to detect powerin the spectrum within and/or around the portion of the frequencyspectrum including the operational channels. Frequency spectralinformation may be collected for any appropriate amount of time, such asfor greater than 24 hours, greater than 48 hours, greater than 3 days,greater than 4 days, greater than 5 days, greater than 6 days, greaterthan 7 days, greater than 8 days, greater than 9 days, etc. Thisinformation may be collected by the access point and/or by the clientdevices, and may be retained locally (e.g., at the AP) and/or storedremotely (e.g., in the cloud). For example, collecting frequencyspectral information may include collecting 7 days or longer offrequency spectral information, e.g., in the access point. Collectingfrequency spectral information may include collecting frequency spectralinformation from each of the one or more client devices (although thenetwork may also include client devices that do not monitor and/orcollect frequency spectral information). Collecting frequency spectralinformation may include collecting frequency spectral informationcovering the portion of the spectrum to be used by the network. Forexample, any appropriate frequency spectral range may be included, e.g.,5 GHz to 6 GHz (e.g., covering the 5 GHz band), 2.4 GHz to 2.5 GHz(e.g., covering the 2.4 GHz band), 3.60 to 3.70 (e.g., covering the 3.6GHz band), 60.0 to 61.0 GHz (e.g., covering the 60 GHz band), etc.

The frequency spectral information may be collected at any appropriaterate. For example, collecting frequency spectral information may includecollecting frequency spectral information at least once every hour fromone or more of the one or more other devices (e.g., once every minute,once every 2 minutes, once every 5 minutes, once every 10 minutes, onceevery 15 minutes, once every 20 minutes, once every 30 minutes, onceevery 45 minutes, once every hour, once every 2 hours, once every 3hours, once every 4 hours, once every 5 hours, once every 6 hours, onceevery 7 hours, once every 8 hours, once every day, etc.).

Usage data may be collected at the access point for all or some of thedevices (e.g., client devices, CPEs, etc.). In general, usage data mayrefer to the strength of the signal between the device and the AP towhich it is communicating. For example, collecting the usage data mayinclude collecting transmitted and received signal strength for the oneor more other devices wirelessly connected to the access point.Collecting the usage data may include collecting data including thepercentage of time that the one or more other devices are using achannel. Any other usage data for the devices connected to the networkmay be used or included.

In general, all or a subset of the client devices connected to theaccess point may be used to determine then spectral efficiency of aplurality of different frequencies for different channels. In somevariations a subset of the client device may be used. For example, theclient devices may be ranked or weighted and these rankings/weights usedto calculate the spectral efficiency. In general for each device (e.g.,for each client device communicating with the access point), thespectral information for that device and the signal strength forcommunication between the device and the AP may be used to determine adata rate (expected data rate) or capacity. For example, the signalstrength and historical frequency spectral information may be used todetermine a signal to interference plus noise (SINR) that, in thecontext of each device (e.g., client device) communicating with the APmay be used to determine a data rate. For example, a lookup tablespecific to each client device (or type of client device) may be used todetermine data rate from SINR. The data rate can then be divided by thechannel width to give spectral efficiency. When there are multipledevices in the network (e.g., multiple client/CPE devices), the datarates may be combined (e.g., the mean, median, weighted average, etc.)in some way, or the maximum or minimum average may be used. In somevariations, only the lowest (worst case) or highest (best case) or somenumber of lowest or highest data rate devices may be used to determinean aggregate data rate that can be used to determine the spectralefficiency. Alternatively or additionally, the aggregate date rate forthe network that may be used to determine overall spectral efficiencyfor a frequency may be determined by using a subset of devices that meetsome predetermined criterion. For example, only devices that are in thetop n devices based on their station efficiency, as described above, maybe used to determine spectral efficiency.

Thus, a set of spectral efficiencies for different channels may bedetermined and this set of spectral efficiencies may be ranked (e.g.,highest to lowest spectral efficiency). Thus, determining a ranking ofspectral efficiency for each of a plurality of frequency channels mayinclude determining a channel capacity for each of a plurality ofchannels (e.g., by determining an average or minimum data rate from thecollected spectral information) and dividing the channel capacity by thechannel width.

Also described herein are apparatuses that are configured to optimizethe channel selection, and in particular, described herein are accesspoints that are configured determine optimal frequency channels within arange or frequencies based on the usage information and historicfrequency spectral information for client devices that are in wirelesscommunication with the access point. For example a wireless access pointdevice configured to optimize channel selection for the access point mayinclude: a wireless radio; an antenna; and a controller configured tocollect, receive, and store 24 hours or longer worth of frequencyspectral information, and to receive and store usage data for one ormore devices that is wirelessly connected to the access point; whereinthe controller is configured to determine a ranking of spectralefficiency, in bit per second per a channel width, for a plurality offrequency channels based on the collected frequency spectral informationand the usage data, and to either present one or more of thehighest-ranked frequency channels or automatically select the channelfor the access point based on the determined ranking.

The controller may be configured to automatically set the channel of thewireless radio based on the highest-ranked frequency channel. In methodsand apparatuses for automatically selecting the channel, a minimum dwelltime may be used (and may be preset or user adjustable). The channel maynot be changed until the minimum dwell time has expired (e.g., 1 second,10 seconds, 30 seconds, 1 minute, 2 minutes, 5 minutes, 10 minutes, 15minutes, etc.).

The methods and apparatuses described herein may be configured so thatthe user may be shown a figure representing a range of frequencies andthe best (optimized) channels indicated, as well as their score (e.g.,the spectral efficiency) shown. In some variations the user may alsomanually select or input a particular frequency and the spectralefficiency for this channel may also be shown. The user may alsomanually enter the channel width (or may select a channel width from amenu of options) and/or may select the frequency range of interest to beoptimized within. Thus any of the apparatuses described herein may beconfigured to output the one or more of the highest-ranked frequencychannels to a display device. For example, the controller may include ormay communicate with a graphical user interface that is configured todisplay frequency spectral information at different frequencies andlabel one or more of the highest-ranked frequency channels on thedisplay. For example, the controller (AP) may host a device-specificaddress that displays and receives (e.g., user input) any of theinformation described herein. Alternatively or additional the AP may beconfigured to transmit the information to a third-party server or devicefor display.

In general, any of the devices (e.g., AP devices) described herein mayinclude an output configured to output the one or more of thehighest-ranked frequency channels.

The controller may be configured to collect frequency spectralinformation for 48 hours or longer.

A method of selecting a channel frequency and bandwidth to change anetwork comprising an access point and a plurality of stations to mayinclude: receiving from a spectrum analyzer at each of the stations adescription of the power in a plurality of frequencies at one or moretimes to determine an ambient noise floor for each frequency in theplurality of frequencies; weighting each ambient noise floor by a factorweight specific to each frequency; determining a goodness of each of aplurality of channels based on the weighted frequencies; and presentinga list of the plurality of channels ranked by the determined goodnesses.

A method of selecting a channel frequency and bandwidth to change anetwork comprising an access point and a plurality of stations to, themethod comprising: receiving from a spectrum analyzer at each of thestations a description of the power in a plurality of frequencies at oneor more times to determine an ambient noise floor for each frequency inthe plurality of frequencies; determining an achievable data rate for aplurality of channels; determining a goodness of each of channel of theplurality of channels based on the ambient noise floor for a subset ofthe plurality of frequencies within each channel and the determinedachievable data rate of each channel; and presenting a list of theplurality of channels ranked by the determined goodnesses.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graphical representation of an indicator of the efficiencyof an access point for monitoring the health of an AP of a wirelessnetwork, shown as a bar chart. In this example, a subset of the stationscommunicating with the AP (e.g., n=10) are labeled and the stationefficiency (as described herein) is shown on the y axis while stationaverage active airtime (as described herein) is shown on the z axis.

FIG. 2 is another variation of an indicator of the efficiency of anaccess point for monitoring the health of an AP of a wireless network,shown as a radial chart. In this example, a subset of the stationscommunicating with the AP (e.g., n=10) are labeled and the stationefficiency (as described herein) is shown as the radial distance, whilestation average active airtime (as described herein) is shown as theangular distance.

FIG. 3 is an example of Merlin and WASP (Qualcomm Atheros Wifi chipsets)code that returns transmit duration, the duration of successful attempts(which can be 0 for a total failure), and the total duration of thefailed attempts.

FIGS. 4A and FIG. 4B are examples of Merlin and WASP (Qualcomm AtherosWifi chipsets) code for functions that can account for the airtime usedby each packet and that reset the accumulation after an elapsed intervaland does the averaging.

FIG. 5 is an example of a display showing an EVM histogram and aconstellation diagram illustrating a snapshot of the performance of anexemplary wireless radio/antenna system.

FIG. 6 illustrates one method for generating a histogram of EVM (e.g.,CINR) values as described herein.

FIG. 7 is another example of a constellation diagram that may begenerated, e.g., using pseudo-EMV points illustrating the distributionof the EVM around ideal points, as illustrated herein.

FIG. 8 illustrates a magnified view of the distribution of pseudo-EVMpoints in the constellation diagram of FIG. 7.

FIGS. 9A-9C illustrate variations of exemplary user interfaces (Us)showing the use of constellation diagrams and histograms of EVM (CINR)data as described herein.

FIG. 10 is a table illustrating parameters and variables for onevariation of a method of determining constellation plots and/orhistograms.

FIGS. 11A and 11B illustrate exemplary EVM packets (e.g., soundingpackets/EVM measure requests and EVM reports).

FIG. 12 is one example (shown as Matlab code) of a method fordetermining the standard deviation of the EVM (estimated EVM) that maybe used to generate a constellation diagram as described herein.

FIGS. 13A-C are examples (shown as Matlab code) of a method for lookingup various QAM “clean” (e.g. ideal) points.

FIGS. 14A-C are examples (shown in Matlab code) of a method forgenerating Gaussian noise samples for the estimated EVM values to createthe cloud of points representing the distribution of EVM values in aconstellation diagram.

FIG. 15 is an example (shown as Matlab code) of a method that may beused to calculate bin placement of estimated EVM (CINR) values whengenerating a histogram.

FIG. 16 is another example of a graphical representation of an indicatorof the efficiency of an access point for monitoring the health of an APof a wireless network, shown as a bar chart.

FIG. 17 schematically illustrates center frequency and bandwidth.

FIG. 18 graphically illustrates the difference between receive powerlevel, ambient noise floor, and thermal noise, and the instantaneouscarrier to interference noise ratio (CINR).

FIG. 19 schematically illustrates one variation of a method ofdetermining goodness of a channel based on estimated achievable datarate of that channel.

FIG. 20 schematically illustrates one variation of a method of a methodof determining goodness of a channel based on average achievable datarate.

FIG. 21 schematically illustrates one variation of a spectruminformation packet.

FIG. 22A shows one example of a calculation to determine goodness over abandwidth.

FIG. 22B schematically illustrates one variation of the use of channelinformation and information from the connected device(s) to determinethe “goodness” of the bandwidth.

FIG. 23 is an example of a method of determining spectral efficiency ofa plurality of channels within a frequency range.

FIG. 24A illustrates one example of a user interface showing some of thenetwork metrics described herein, including pseudo-dynamic constellationdiagrams. FIG. 24B shows the user interface of FIG. 24A with a channeloptimization tool overlaid on top of the user interface. FIG. 24C is anenlarged view of the channel optimization tool, showing an example of anoutput of the channel optimization; this tool may also be used toprovide user control of some of the parameters used to optimize thechannel selection (e.g., frequency range, channel bandwidth, etc.).

FIG. 25 illustrate another example of an output (optimization tool) foroptimizing the channel selection of a network (e.g., an access point).In this example, the AP has not yet calculated/optimized channels basedon spectral efficiency because the channel bandwidth (channel width) hasnot been selected. The tool in this example, is a user interface thatshows other devices (client devices) wirelessly communicating with theAP, as well as a graphical indicator (heat map) of the frequencyspectral information for each device.

FIG. 26 is a another example of the graphical output (tool) of an APshowing the top 3 channels based on the determination of rankings ofspectral efficiency as described herein.

FIG. 27 is another example of the AP tool for optimizing the channelselection shown in FIGS. 25 and 26 with a different channel width (e.g.,60 MHz) selected.

FIG. 28 is another example of the AP tool shown in FIGS. 25-27, with aselected channel width of 30 MHz and a narrower frequency range tooptimize over.

FIG. 29 is an example of an AP tool (graphical output) for an AP that isconfigured to optimize channel selection. In this example, the AP isoperating in a point-to-point (PTP) configuration. In this example, theAP outputs a pair of graphs showing the local frequency spectralinformation for the AP (top, local) and the device it is communicatingwith (bottom, remote). The tool is otherwise similar to the variationshown in FIG. 25.

FIG. 30 illustrates another example of the apparatus of FIG. 29, inwhich the channel width has been selected, and the top three channelshaving the highest spectral efficiency for this bandwidth indicated.

FIG. 31 is another example of the apparatus of FIG. 29, showingselection of a different channel width (e.g., 30 Mhz) resulting indifferent optimized channels.

FIG. 32 is another example of the apparatus of claim 30, illustratingthe selection of a narrower frequency band to optimize over (similar tothe point-to-multipoint example shown in FIG. 28).

FIG. 33 is a schematic illustration of an apparatus (e.g., AP)configured to optimize the channel selection as described herein.

DETAILED DESCRIPTION

Described herein are apparatuses and methods for monitoring networkhealth, including in particular, the health of an access point (AP). Thehealth may be determined and presented as a graphic metric that quicklyand usefully informs (at a glance) a network operator (e.g., administer,WISP provider, etc.) of other provider servicing a network, informationabout the overall and specific efficiency of the network (e.g., AP). Forexample, described herein are systems and methods for preparing anddisplaying a metric, including graphical metrics, of the health of thenetwork. A system may include, for example, non-transitorycomputer-readable storage medium storing a set of instructions capableof being executed by a processor that cause the processor to present themetrics described.

In general, the metrics described herein present a selected and relevantsubset of information from the network that is most relevant to overallhealth as may be required by a network operator. This information isgenerally determined in a periodic basis and updated, and may include orincorporate both the most recent (e.g., within the last few seconds tominutes) as well as recent historical information (e.g., from theprevious minutes, hours, days, weeks, months, etc.).

Part I: Devices (e.g., CPE) Network Ranking

As mentioned, the overall network (or partial network) health, includingin particular the health of one more access point of a network, may bemonitored by providing information to/from each (e.g., all or most) ofthe stations communicating with the access point within a predeterminedperiod of time (e.g., hours, days, weeks, months, years) and using asub-set of these stations (e.g., the “top” stations) to present withinformation about their impact on the network/access point. Generally,the information used to determine these metrics may be monitored at theaccess point and at the station and exchanged between them. Thisinformation may be stored and otherwise manipulated to determineestimates for overall efficiency of each station as well as actual usageinformation. In general, this information may include the most recenttime period/interval (e.g., sample period of 30 seconds) and/or it mayinclude (or may not include) historical information, which may beweighted so that current data is either emphasized or de-emphasized.Also, in any of the variations described herein the efficiency andactivity time for each station may be empirically determined and/or maybe compared with ideal or projected information, based on equipmentspeculations,

For example, in general, the transmit air-time of a packet between eachstation and access point may be tracked. This is the actual air-timeused by a packet, including all retries. This is calculated after thetransmission is complete. For each packet the following may be used:Total packet transmit duration: Dt; Duration of failed attempts: Df;Duration of successful attempts: Ds. In general, Dt=Df+Ds.

An example Merlin and WASP (Qualcomm Atheros Wifi chipsets) code isshown in FIG. 3, that returns the actual transmit duration and alsoreturns the duration of the successful attempt (which can be 0 for atotal failure), and the total duration of the failed attempts.

Per-STA TX packet air-time and error-rate accounting may also bedetermined between access point and each station. This may be done usingsimple accumulate and average mechanism. For example, Dt value for thepacket may be accumulated on a per-STA basis into a “totalaccumairtime”variable. This may be done over time ‘Ai’ which is the averaginginterval. Similarly, the Df and Ds values may be accumulated on aper-STA basis (totalaccumfail and totalaccumsucc). Once we haveaccumulated for more than Ai amount of time, i.e., elapsed durationDe>Ai, the airtime-usage percentage for the current elapsed period maybe calculated, e.g., as follows: airtime=(totalaccumairtime*100)/De

Similarly, the packet error rate for the current elapsed period may becomputed as: per=(totalaccumfail*100)/(totalaccumsucc+totalaccumfail).

Note that this automatically adds more weight to the packets that arelonger in duration as compared to simply counting successful and failedattempts.

The airtime and PER for the current elapsed period may then be added,into an average. In one example, using exponential average:avg_airtime=(avg_airtime+airtime)/2 avg_per=(avg_per+per)/2.

After the averaging, accumulation variables may be reset:totalaccumairtime=totalaccumfail=totalaccumsucc=0. The procedure foraccumulation-reset may also need to be called when a remote (e.g.,cloud) agent accesses these values to construct a heartbeat if therewere no further transmissions to the STA that causes the accountingfunction to execute.

Example Merlin and WASP code is shown in FIGS. 4A and B, showing anexemplary function (_do_sta_packet_accounting) that accounts for theairtime used by each packet, and a function (_do_sta_tx_stats_refresh)that resets the accumulation after an elapsed interval and does theaveraging. For example, _do_sta_packet_accounting may generally becalled only during a TXDONE operation. But in the event where there weresome transmissions to the station and none after that, the_do_sta_tx_stats_refresh function must be invoked at the time when thecloud agent sends the heartbeat.

The downlink and uplink airtimes may also be determined. For example, onan AP, the routines described above will account for the ‘DOWLINK’portion of the airtime and packet-error-rate for each station. On theSTA, the routines will account for the ‘UPLINK’ portion of the airTimeand packet-error-rate for the STA→AP direction. Polling protocolmodifications are required for AP and STA to communicate these values toeach other so that total airTime can be determined

As mentioned, polling protocol modifications may be made. As part of thepolling protocol in the poll response packet's statistics section (sentby the station) a system may communicate the station's airtime andpacket-error-rate to the AP. The statistics portion may typicallyalready contain the current rate-control's PHY rate in Kbps and the maxpossible PHY rate according to chain-mask. For example, in some systemsthe AP already evaluates the statistics of each STA. As part of thatprocess, the AP updates the stations TX airtime and per intocorresponding RX fields. For example, sta→rx_airtime_avg andsta→rx_per_avg.

In the same way, as part of the poll request packet's statistics section(sent by the AP), a system may communicate the station's TX airtime andpacket-error-rate to the STA. The STA may also update the TX airtime andPER into corresponding TX fields.

In general, downlink/uplink isolated capacity may be determined. Forexample, ISOLATED_CAPACITY may be determined asISOLATED_CAPACITY=(PHYRATE*MAC_EFFICIENCY_PERCENT*(100−PER))/10000.Since we may have PHYRATE and PER in both directions we will have twoseparate values Downlink-Isolated-Capacity and Uplink-Isolated-Capacity.MAC_EFFICIENCY_PERCENT may be a system based constant. For example, inan 802.11ac system, 75% may be used and/or may be empiricallydetermined. In other words, these values may indicate potentialthroughput if the station were using the network alone (i.e. isolated).

This value may be confirmed to confirm that a Subscriber is not RFlimited, i.e., the operator may oversubscribe his AP but the RFcharacteristics may be fine, and in this case the actual throughput maybe lower, but it is not lower because of RF for which he may need totake some action.

Total airtime and isolated capacity may be determined. The TOTAL_AIRTIMEmay be the sum of DOWNLINK and UPLINK airtimes. TheTOTAL_ISOLATED_CAPACITY is typically the average of DOWNLINK and UPLINKisolated capacity.

As mentioned above, in general, the methods and systems described hereinmay be operated, refreshed and/or updated during a remote (e.g., cloud)agent “heartbeat”. In general the heartbeat is the transmission ofoperational parameters from the stations and/or AP to a remote site(e.g., a cloud server or the like) and/or to the AP or another AP. Thisheartbeat is transmitted at regular intervals, such as every 30 seconds(or any other appropriate time period). The cloud heartbeat maycommunicate the average-airtime (both directions), average-per,phy-rate, max-phy-rate, downlink-capacity, uplink-capacity to the cloud.

Computations may be performed remotely, including on the cloud. On thecloud, the following computations may be done at each heartbeat (inaddition to storing the current heartbeat values into storage):

    IF HEARTBEATS_SINCE_RESET > WINDOW_SIZE     THEN        ACTIVE_AIRTIME_COUNTER /= 2         ACTIVE_AIRTIME_ACCUMULATION/= 2         HEARTBEATS_SINCE_RESET = 0     ENDIF     IF TOTAL_AIRTIME >Y THEN         ACTIVE_AIRTIME_ACCUMULATION +=         TOTAL_AIRTIME        ACTIVE_AIRTIME_COUNTER++         AVG_ACTIVE_AIRTIME =(AVG_ACTIVE_AIRTIME + TOTAL_AIRTIME)/2     ENDIF    HEARTBEATS_SINCE_RESET++     WINDOW_SIZE may be defined based on thenormal heartbeat interval to prevent any overflows.

For a 30-second heartbeat, there will be 2880 heartbeats in a 24-hourwindow. Hence WINDOW_SIZE can be defined as 2880. The above codeaccumulates the periods of air-time when the station's activity wasgreater than Y. Y should ideally be defined as the100/NUMBER_OF_STATIONS_ON_CONNECTED_AP. So for an AP with 50 stations, Ywould be 2% for fair-sharing the network. And in such a case weaccumulate airtimes for times-when the usage is above the 2%.

The Accumulation is reset by half after we cross the window-size. Thiswill essentially use ½ weight for past data.

Station efficiency may also be estimated or calculated. For example, theefficiency of the STATION is computed by a simple ratio of its totalisolated capacity to the AP_MAX_CAPACITY as a percent:STA_EFFICIENCY=(TOTAL_ISOLATED_CAPACITY*100)/AP_MAX_CAPACITY

Where:

AP_MAX_CAPACITY=(MAX_PHY_RATE_OF_AP*MAC_EFFICIENCY_PERCENT)/100

As mentioned above, when preparing to determine the visual display (andthe analysis of network/AP health), the “top” users may be determined.In some variations these top users may be determined on the cloud. For agiven AP, the method (or a processor, including a remote or “cloud”server) may get a station list, listing all of the stationscommunicating with the AP during the predetermined time interval (e.g.,hours, days, weeks, months, etc.). For each station, the system (ormethod) may compute a Usage-Index (“Ui”) as follows:

Ui=ACTIVE_AIRTIME_ACCUMULATION/ACTIVE_AIRTIME_COUNTER

The stations may then be sorted as follows: (1) by HIGHER Ui value; (2)if two stations have the same Ui value, sort by LOWERTOTAL_ISOLATED_CAPACITY. From this sorted list selected the first N.This will be the TOP-N users over the last 24 hours. The ‘TOPNESS’ isnot necessarily according to just airTime, but also according tolower-capacity and airTime, and by clients that are bursty. For example,n may be 10 (though any appropriate number may be chosen).

Graphical Display

In preparing a display, the method or system may present a “TDMA window”graph, as shown in FIG. 1. In this example, the image is formed bysorting the TOP-N stations determined above by the STA_EFFICIENCY indescending order. The AVG_ACTIVE_AIRTIME value is used for thehorizontal axis, and the STA_EFFICIENCY for the vertical axis. Themaximum value for the vertical axis is the AP's maximum possiblecapacity value=AP_MAX_CAPACITY. In FIG. 1, the maximum value of thehorizontal axis is the SUM_OF_TOP_N(AVG_ACT_AIRTIME) value.

The AP efficiency may be immediately and intuitively determined fromFIG. 1 based on the overall amount of shading 102. For example, theefficiency of the AP can be considered as the area of this shaded 102(colored) area, compared with the unshaded 105 region. In FIG. 1, eachstation may be uniquely identified by a color; the stations may also belabeled or identified when clicking on or “mouseing over” the shadedregion corresponding to the station. As a consequence of thetechnique/system described above, only the TOP-N stations selected aboveare considered in determining the efficiency of the AP. Thus:

AIRTIME_SUM=SUM_OF_TOP_N(AVG_ACT_AIRTIME)

WEIGHTED_AIRTIME_EFF=SUM_OF_TOP_N(AVG_ACT_AIRTIME*STA_EFFICIENCY)

AP_EFFICIENCY=(WEIGHTED_AIRTIME_EFF*100)/(AIRTIME_SUM*AP_MAX_CAPACITY)

As mentioned above, any appropriate graphical presentation or techniquemay be used to display this information. For example, FIG. 2 illustratesanother graphical depiction of the network health, in which a radialaxis is used. In this example, the AVG_ACTIVE_AIRTIME value is shown asthe angular distance (portion of the circle), while the STA_EFFICIENCYis shown for the radius of each segment of the circle corresponding tothe individual stations (ranked by top stations). AP efficiency may beimmediately and intuitively determined from FIG. 2, as above for FIG. 1,based on the overall amount of shading 202 compared to non-shadedregions 205.

Estimating and Displaying Error Vector Magnitude

Any of the systems described herein may generate a histogram and/orconstellation diagram based on the Error Vector Magnitude (EVM). An EVM,sometimes also called receive constellation error or RCE, istraditionally a measure used to quantify the performance of a digitalradio transmitter and/or receiver. As described above, a signal sent byan ideal transmitter or received by a receiver would have allconstellation points precisely at the ideal locations (depending on themodulation type), however imperfections such as carrier leakage, lowimage rejection ratio, phase noise etc., may cause the actualconstellation points to deviate from these ideal locations. EVM may bethought of as a measure of how far the points are from the ideallocations. Noise, distortion, spurious signals, and phase noise alldegrade EVM, and therefore EVM provides a measure of the quality of theradio receiver or transmitter for use in digital communications.

Although traditionally transmitter EVM is measured by specializedequipment, which demodulates the received signal in a similar way to howa real radio demodulator does it, it would be helpful to provide ameasure of EVM (and graphical presentation of EVM) that may be quicklyand easily determined and displayed during normal operation of a radio(transmitter and/or receiver).

An error vector is a vector in the I-Q plane between the idealconstellation point and the point received by the receiver. In otherwords, it is the difference between actual received symbols and idealsymbols. The EVM may be thought of as the average power of the errorvector, normalized to signal power. For the percentage format, root meansquare (RMS) average may be used. The EVM may be equal to the ratio ofthe power of the error vector to the root mean square (RMS) power of thereference. EVM, as conventionally defined for single carriermodulations, is a ratio of a mean power to a peak power. Because therelationship between the peak and mean signal power is dependent onconstellation geometry, different constellation types (e.g. 16-QAM and64-QAM), subject to the same mean level of interference, will reportdifferent EVM values. EVM, as defined for multi carrier modulations, maybe a ratio of two mean powers regardless of the constellation geometry.In this form, EVM is related to Modulation error ratio, the ratio ofmean signal power to mean error power.

As used herein, carrier to interference noise ratio (CINR) is anexcellent proxy for EVM. For example, in implementation, soundingpackets specific to two or more known (predetermined) modulation typesmay be transmitted and received between devices (e.g., between AP andCPE). The receiving hardware may detect the received packet, and analyzethe descriptors in the packet to determine an estimate for EVM based onthe carrier to interference noise ratio. For example, the hardware maydetect a particular sounding packet (corresponding to a particularmodulation type), and may analyze descriptors from the packet, and thisinfo may be is embedded in an EVM signal that is reported for concurrent(immediate or slightly delayed) or later (historical) display, e.g., asa histogram and/or constellation diagram.

This determination of EVM (using predetermined sounding packets) may beperformed by all or some of the radios in the network (e.g., and may bedesigned and/or built-in to the chipset of the radio). The EVMdetermined in this way (and described in more detail below) may providean approximate estimate of the EVM for the connection between devices,and may be displayed/presented or used as an indication of thetransmission quality, which may be measured by the device thatdemodulates the signal and calculates the noise. For example, the EVMthat the device reports (e.g., and this report may be made to a node,such as an AP and/or may be transmitted to a remote location, such as aserver), may be more of than just SNR information. The EVM may make useof pilot signals embedded in the packet; the device(s) typically detectthe pilot (sounding) signal and know what it should be, and may thencalculate the SNR of the pilot signal. This may be reported as the EVM(e.g., CINR, or carrier to interference noise ratio).

As mentioned above, the EVM estimates (EVM) measured over a period oftime as described herein may be shown using a histogram. For example, anEVM measurement may be determined between a two (or in some cases more)devices for each sounding packet or set of sounding packets (where a setmay correspond to a complete set of predetermined modulation types,e.g., MCS 3, 5, and 8, in reference to the table of FIG. 10, describedbelow, in which MCS 3 corresponds to modulation type and coding rateBPSK, MCS 5 is 64QAM, and MCS 8 is 256QAM.

For example, a histogram may take 64 samples of measured EVM and usethem to display histogram (CINR histogram or EVM histogram) thatvisually shows the EVM (based on this window of time needed toaccumulate the 64 samples). As will be illustrated below, thesehistograms, which aggregate the estimated/approximated EVM based onsounding packets for two or more (e.g., three or more, e.g., four ormore) modulation-specific sounding packets, for a window of timecorresponding to x received EVM estimates. E.g., the histogram for CINR(estimated EVM) may indicate that the link has better than 20 dBCINR/EVM, but also indicates a cluster near the low 10-20 dB range.

As mentioned, in general, the use of these modulation type-specificsounding packets may allow estimation of EVM. Because of this, theestimated EVMs described herein may also be referred to as SNR at thereceiver, which may include distortion in the transmitter in thetransmitted signal, and may also include thermal noise at receiver andinterference channel. Although it may be desirable to eliminate thetransmission distortion (depending on the MCS that was transmitted), ingeneral, different MCS (modulations) transmit with differentdistortions, because of a tradeoff in power and mode. Transmitting atlower power may result in clearer transmission for high QAM (lessdistortion). For example, a device (e.g., an AP) may periodically sendtest packets (sounding packets) at different MCS rates for the clientsmeasuring the EVM, and vice-versa. These test (sounding) packets aretypically not data packets. When a sounding packet is received by thedevice (e.g., AP) from another device (e.g., a CPE), the first devicemay receive it and/or broadcast it (or the information received from it.As mentioned, the sounding packets may cycle through all or a subset ofthe different modes used between the devices. See, e.g., FIG. 10.

For example, in some variations, three modulations are use (e.g., BPSK,64QAM and 256QAM). If a packet is sent at high MCS (e.g., 256QAM), arelatively high SNR may be needed in the link for the receiver toreceive it. If the devices in the link are too far apart, for example,the receiver may not be able to receive it, though a lower MCS may beneeded to receive e.g., BPSK. However, as mentioned, at this low MCS,the packets may be heavily distorted. For example when transmitting atBPSK, the packet may never be received at an EVM in excess of 15 dB;there may be lots of noise coming from the transmitter. Thus in general,BPSK may be transmitted at high power and allow more distortion. Thesystem(s) may deliberately allow transmission to be distorted at thetransmitter to get high transmission power, as a tradeoff between theMCS rate and the EVM that the system estimates. In practice, in somevariations only a subset of the possible modulations (MCS) may bemeasured for the purposes of measuring EVM (CIPC) as described herein.For example, three MCS types may be used.

Examples of exemplary EVM packets (e.g., sounding packets/EVM measurerequests and EVM reports) are shown in FIGS. 11A and 11B. For example, asounding packet may include a normal preamble and then may have basicinformation in the MAC layer (e.g., MAC ID of the device sending thepacket, and ID to the MCS, and identify the MAC layer that alsoidentifies that it's a sounding, e.g. test, packet).

An EVM sounding packet may be communicated at regular intervals (e.g.,every 5 sec) and the device may determine from the sounding packets anestimate of CINR (which may be used to estimate EVM). As will bedescribed in greater detail below, this estimate may be displayed, e.g.,in a user interface as either or both a histogram or as an estimate of aconstellation diagram. This display me be static/average, or it may bedynamic (and updated periodically). In some variation the display, andin particular, the displayed constellation diagram, does not show actualmeasured points, but an approximation of these points based on thestatistical distribution of the values for the estimated EVM. Thus, theactual point location on the constellation diagram may be apseudo-representation of the actual point, so that the actual positionof the points on the constellation diagram (relative to the ideallocations) is false, but the overall distribution of points is accurate.Thus, the general impression (familiar look and feel) provided by theconstellation diagram is correct, even if the specific locations of thepoints are estimated.

The use of the histogram to display estimate EVM (e.g., CINR) may beparticularly helpful as interference may be transient. These histogramsmay be shown with (e.g., alongside) a constellation diagram. Either orboth the histogram and constellation diagram may be displayed as(showing the I and Q components) as an animation. As mentioned, theconstellation diagram may be a dynamic recreation of what a more preciseEVM testing equipment would show, using pseudo-locations for EVM basedon the estimates provided by the sounding packets. Thus, the userinterface (UI) may create a real-time animation displaying the estimatedEVM.

In general, a connection between two or more devices (radio devices)forming a link may estimate EVM and this information may be displayed asone or more constellation diagram and/or histogram. For example, eachdevice forming the link may send sounding packets to seatmate EVM(CINR). Sounding packets maybe sent at particular MCSs to measure therange of EMVs. For example, an AP may broadcast the sounding packets toone or more CPE; the CPE may transmit sounding packets (and informationgleamed from the received sounding packets) to the AP. The informationreceived and/or determined from the sounding packets may be held locally(e.g., at the AP) and accessed from the AP directly, and/or transmittedto a remote site (e.g., a cloud location) that may be remotely accessed.The devices and/or the system may use the statistics from the EVMestimates based on the sounding packets to build an EVM histogram and/orconstellation diagram. Because the method uses “standard” soundingpackets, the result is a reliable indicator, because it does not reportraw (e.g., I and Q) samples. Instead, the devices/system may usestatistics provided by the radio. The sounding packets chosen may beselected to span the range (dB) of EVM for the link(s), and thus thesounding packets chosen may be used to determine a minimum number tospan the entire EVM range.

For example, a BPSK sounding packet may only measure/reflect a range of0-10 dB, and may not measure outside of this range because BPSK isinherently distortive. If a sounding packet is based on 16QAM, the rangemay be good from 0-20 dB, but the sounding packet may not be heard byall of the clients (e.g., if transmitting by AP). In practice, theanalysis (e.g., at an AP) may use the “best” sounding packet from theset of MSC packets; typically the highest MCS sounding packet that wasable to receive for a link. The CINR may include the transmissiondistortion, which may be loudest in low MCS packets. The transmissiondistortion may mask the SNR.

As will be described in more detail below, a user interface may data(histogram and/or constellation diagrams) for one or more links or endsof the link. For example, a user logging into a user interface may bepresented with the histogram and/or constellation diagram for the EVM(CINR) at the access point; however the user may select displays of oneor more CPEs that a particular AP is communicating with. Additionalinformation, such as link capacity, signal to noise ratio, remote and/orlocal signal strength, thermal noise, etc., may also or alternatively beshown, on the same, or a different, screen.

FIGS. 5-6 and 9A-9C illustrate examples of histograms of EVM (CINR). Inthese examples, the histogram looks at the frequency distribution ofdifferent EVMs. This distribution in this example is a rolling window of(e.g., 64) different values of EVMs reported by the device(s). Forexample, a sounding packet may be received at predetermined intervals,e.g., every 5 seconds. Thus, the histogram and/or constellation diagrammay update every time a new sounding packet (or new set of soundingpackets spanning the set of MSCs examined) is received. For example, ahistogram may update every 5 sec, when a new sample in the slidingwindow of 64 samples is generated. If the device/system does not receivea test packet, it may assume that there is interference at that MCS.When a full set of test packet includes 3 MSCs (e.g., BPSK, 16QAM,256QAM), the device/system may determine that there are 3 types of testpackets transmitted as different MCSs, and if they do not receive one,it may assume that there was interference; when it does not receive thepacket, the device/system may update it as a 0 dB EVM (minimum possibleEVM). The device/system typically keeps track of the sequence number anddetermines if one or more packets was not received, and uses thisinformation to estimate/determine the EVM. Thus this information may beused as interference metric, which may be particularly helpful indetecting and/or indicating transient interference. For example, threeMSC types of sounding packets may be used (e.g., a BPSK sounding packetreflecting the 0-10 dB range, a 64QAM packet reflecting the 0-15 dBrange, and a 256QAM packet reflecting the 0 db-30 dB range). Theapparatus/system may use the information for the highest modulationused. For example, if the apparatus/system receives the 256QAM packet,it may use only this member of the set (rather than the BPSK or 64QAMpackets), assuming that this most accurately reflects the CINR (e.g.,the other packets may be discarded). For example, if they get the 64QAMpacket, it may use just the 64QAM packet (as the frequency number forthe packet is typically known).

In some variations, multiple histograms may be generated based on thedifferent sounding packets (e.g., different MCSs). For example, wherethree modulation types are used, three histograms may be generated; theCINR between them may change due to interference. The system may choosethe appropriate MCS level based on the range, e.g., the distance betweenthe ends of the link (e.g., between the AP and CPE). This may beaccomplished over time by looking at the best MCS (sounding packet) thatis consistently received.

For example, FIG. 5 schematically illustrates on example of a histogram(top) and constellation diagram for a single stream of one link. FIG. 10illustrates exemplary parameters and variables that may be used inestimating the EVM/CINR and generating the histogram and/orconstellation diagram. In FIG. 5, the constellation diagram shows anapproximated (pseudo-valued) distribution of EVM points (solid dots)around ideal locations (circles) for each of the 16 locations in a 16QAMmodulation.

An EVM histogram (which may also be referred to as a CINR histogram) maybe generated for each end of a link. For example, the firmware/hardware(e.g., driver) of a radio apparatus may be configured to provide a blockof EVM samples (“EVM_samples”) that are obtained as described above,e.g., from received packet descriptors corresponding to special EVMmeasurement packets (sounding packets). In one example, the block lengthof the EVM samples is NUM_EVM_SAMP (with default value of 64). Thehistogram may be generated by first generating EVM_hist[NUM_EVM_BINS]which represents the histogram of EVM values measured. More precisely:EVM_hist[i_EVM_bin] may correspond to the number of occurrences of theEVM values MIN_EVM+(i_EVM bin−1)*DEL_EVM in the samples set EVM_samples.

The EVM histogram may be plotted as shown in FIG. 6, where probabilitiesare represented by different shades (which may be displayed in colorshades). We show NUM_EVM_BINS number of patches where the color of thei_evm_bin-th patch is given by the index evm_hist_idx(i_evm_bin),computed as follows:Percent (%) convert to probability: EVM_prob=EVM_hist/NUM_EVM_SAMPPercent (%) compute evm_hist_idx:evm_hist_idx=place_in_bins(EVM_prob,NUM_PRB_BINS,MIN_PRB,DEL_PRB)

FIG. 15 illustrates one example of a method (shows as Matlab code) thatmay be used to calculate bin placement (e.g., “place_in_bins”).

The estimate EMV information (CIRM) may also be used to generate aconstellation diagram, as illustrated in FIGS. 5 and 7-8. As mentionedabove, this constellation diagram may be a pseudo-EVM constellationdiagram, because the EVM is not directly measured, but is instead shownon the constellation diagram based on statistical approximations thatmay accurately reflect the distribution of EVM values, but not actualmeasured EVM values. The ability to rapidly and accurately generateestimated constellation diagrams in this manner is advantageous, becausethese plots, which may be familiar to those using traditionalconstellation diagrams, may be generated without requiring rigorouslygenerated EVM values (e.g., using dedicated systems necessary tocorrectly measure EVM).

For example, a single frame of a constellation diagram is shown in FIG.5 and also in FIG. 7. As mentioned, the constellation diagram may be ananimation, which may be updated at actual update rates (e.g., refreshingas new estimated EVM/CINR is determined), or it may beupdated/animated/refreshed more often, by generating new pseudo-EVMpoints using the same distribution information, as described herein. InFIG. 7, the constellation diagram includes: “clean” constellation pointsshown as open circles (representing the ideal values), and “clouds” ofnoisy samples associated to each constellation point, shown as soliddots. FIG. 8 shows a close-up of a single constellation point and itsassociated noisy sample cloud. The distribution cloud points may begenerated as described below, from the estimated EVM (CINR) data. Forexample, the x,y coordinates of the j-th constellation point may begiven by:

x_pts(j): x-coordinate of the j-th constellation point

y_pts(j): y-coordinate of the j-th constellation point

A total of NUM_NZY_SAMPS noisy samples may be plotted around eachconstellation point. In the above examples, NUM_NZY_SAMPS=7. For thej-th constellation point, NUM_NZY_SAMPS noisy samples may be plotted,which form a “cloud” around it. The x,y coordinate of i-th point in thiscloud may be given by:

x_cld_j(i): x-coordinate of the i-th noisy sample cloud point

y_cld_j(i): y-coordinate of the i-th noisy sample cloud point

Example of one variation of a method for computing these values areshown below and exemplary code for performing these methods is shown inFIGS. 12-15.

For example, the standard deviation of the noise samples may bedetermined. The standard deviation of noise samples, sigma, may be givenby:sigma_average=sqrt(½)*[10^(EVM_samples[i_samp]/20)

If computing power of 10 is computationally intensive, a look up tablemay be used. Exemplary code for this is provided in FIG. 12, showingexemplary Matlab code (though other code performing similar orequivalent functions may be used, as is generally true for the exemplarycode provided herein), described as “look_up_sigma,” for converting asingle estimated EVM value into a single sigma value. Using such afunction it is possible to calculate:sigma_average=look_up_sigma(pilot_EVM[1])

Clean constellation points may be generated (QAM constellation points)for each type of modulation. These points may be stored and looked up.For example, exemplary Matlab code is provided in FIGS. 13A-C(lookup_qam_constellation). In this example, vectors of x and ycoordinates of the constellation points may be given by:[x_pts,y_pts]=lookup_qam_constellation(mod_type)

In the constellation diagram, both “clean” constellation points andclouds of noisy sample corresponding to each constellation point areshown. Each of these “clouds” of points representing the distribution ofEVM values may include NUM_NZY_SAMPS number of noise samples. Forexample, noisy samples (in x and y coordinates) may be generated asfollows:x_nze_j=sigma*get_gaussian_noise_samples(NUM_NZY_SAMPS);y_nze_j=sigma*get_gaussian_noise_samples(NUM_NZY_SAMPS);

An example of a method (encoded as Matlab code) for generating thesecoordinates is illustrated in FIGS. 14A-C(“get_gaussian_noise_samples”). The noise samples may be added to theconstellation points to generate the “noise sample cloud”. For example,for the j-th constellation point samples may be estimated as:x_cld_j=x_pts(j)+x_nzey_cld_j=y_pts(j)+y_nze

FIGS. 9A to 9C show examples of user interfaces that may includepseudo-EVM information in the display, including constellation plotsand/or histograms, as well as (in some variations) additionalinformation about the connectivity of a device (or between the deviceand one or more other devices). For example, in FIG. 19A, the userinterface includes a series of panels or regions (“device”, “wireless”and “RF environment”) describing the status of one or more devices in anetwork. In this example, the device is described as an exemplary radio(transmitter/receiver), corresponding to a model no. “Rocket 5AC PTP”.This device is configured as an access point, and the device tabprovides characteristic information, including model, device name,version, network mode, memory, CPU, cable length, cable SNR, airtime,LAN speed, date and uptime. More or less such information may beincluded. In some variations the device may be selected from a menu ofavailable devices, which may include other (connected) devices. Ingeneral this user interface may be accessed either directly, e.g., byconnecting to a device such as the AP via a plug, cord or local wireless(e.g., Bluetooth, etc.) connection, or indirectly, via a connection to aremote server (e.g., cloud server) that communicates with the deviceand/or aggregates the information from the device.

In FIG. 9A, the middle region (tab) may include information specific tothe wireless system for the particular device, such as the wireless mode(e.g., access point, CPE, etc.), SSID, MAC identification information,security, distance of link, frequency, channel width, signal,transmission rate, receive rate, etc. This information may be specificto a particular link or more than one link; thus, for example, an accesspoint may communicate with multiple other devices (CPEs, etc.), and auser may toggle between these different links, or the information may begeneric to all of the links.

The user interface (including the wireless display portion) may includea graphical illustration of the capacity of the link throughput, asshown in FIG. 9A in the middle right. The graph shown indicates arunning (showing the time axis) value of the capacity of the link.

The bottom region of the user interface shown in FIG. 9A indicates theproperties of the RF environment, including a pair of constellationdiagrams (local and remote) as discussed herein, and EVM (or CINR)histograms adjacent to the constellation diagrams. In this example, theRF environment also shows a running (time axis) view of the signal tonoise ratio of the connection, in FIG. 9A the local SNR values are shown(though the remote values may be selected for display, as shown in FIG.9C).

In the examples shown in FIG. 9A-9C, the local device may refer to thedevice that you are logged into (e.g., when connected either remotely ordirectly), while the remote device typically refers to the other devicein the particular link you are observing. For example, in FIG. 9B, thesignal to noise ratio illustration on the bottom right may be at leastpartially determined from the EVM data, and also shows the noise floor(thermal noise floor) between the two devices. The signal level may bevisualized as the gap between the signal (top trace) and theinterference+noise (middle) traces. The lower trace is the thermal noisefloor. Large SNR is visualized by the gap between the signal andinterference+noise traces.

The constellation diagrams shown in FIGS. 9A-9C may be regularly updated(e.g., animated) either as fast or faster than the actual EVM data istransmitted between the link. This is because the pseudo-EVM data may begraphed by re-calculating new coordinates for the cloud of EVM pointsaround the ideal points in the constellation plots. For example, theplots may be updated approximately 10× per minute or more often (e.g.,10× second, etc.).

In FIGS. 9A-9C, the local constellation diagram is shown as a 16QAMconstellation (having 16 ideal points) for local reception, while theremote constellation diagram is a 256QAM diagram.

In any of the examples described herein, the user interface may includea display of colored symbols, shapes (e.g., boxes), etc., representingthe values for the various devices in the device list, and may alsoindicate device detail in a panel that will help communicate to the userwhere inefficiencies lie. In some variations, this information will beassociated with a particularly access point (AP). For example, displayedcolored boxes may represent the top number (e.g., top 10) airtimeclients in the list, and the user interface may also show additional(e.g., the top 20) airtime clients in the detail view.

Additional information provided by the detail view may includeinformation about the parameters specific to the station (e.g., CPE)represented by the box, wedge or other representation of the value ofthe station. For example, the detail view may allow hovering overrepresentation (e.g., box) for a quick tooltip, and highlighting theoffending device in a list below.

In some variations the detailed list view may also include a number infront to communicate total number of devices, and a percentage ofefficiency. The list user interface (e.g., the list view) may have atooltip, e.g., at the top of the column, to quickly explain what TDMAis. The detailed information (e.g., list view) may also be sortable byTDMA (and other capacity values), e.g., in this column, so efficient orinefficient devices can be shown more quickly, e.g. by bringing them tothe top.

In any of the variations described herein, the TDMA may be calculatedfor past time (historically, e.g., the past 24 hours), rather than (orin addition to) real-time. In the examples described herein, the X axiscommunicates time, proportionally, and the Y axis communicatesthroughput. Colors may also be used to indicate the quality (“goodness”)for individual stations. For example, good clients (e.g., top 33%) maybe colored green, mediocre clients may be colored orange (middle 33%),and bad/inefficient clients may be colored red (bottom 33%). Theremaining areas may be greyed out.

EXAMPLE

The techniques described herein typically relate to time divisionmultiple access (TDMA). TDMA may refer to a channel access method forshared medium networks that allows several users to share the samefrequency channel by dividing the signal into different time slots. Forexample, users may transmit in rapid succession, one after the other,each using its own time slot. This may allow multiple stations to sharethe same transmission medium (e.g. radio frequency channel) while usingonly a part of the channel capacity. As a simplified example, if TDMAwere a party, and there were three guests, Alice, Bob, and Carol talkingto the host, each guest may share time talking with the host. Forexample, for the first 10 seconds, Alice may talk to the host, for thenext 10 seconds, its Bob's turn to talk to the host, for the next 10seconds, its Carol's turn to talk to the host, then for the next 10seconds, back to Alice, then Bob, and so on. Thus, the frequency-rangethat is being used may be divided into time-slots, and each userassigned a specific time-slot; users can only send/receive data in theirown time-slot. The system may also be configured so that users (devices)may forfeit their time slot (e.g., by analogy, if a guest decides theyhave nothing to say, they may give up their slot and somebody may useit; thus, if there are 14 people at the party, and only one is beingchatty, you avoid long awkward pauses every time that user is done withher slot).

In general, Wi-Fi standards typically have a theoretical speed at whichthings can operate, e.g. 802.11b at 11 Mbps, 802.11g at 54 Mbps, 802.11nat 300 Mbps, 802.11ac at 1.3 Gbps etc. The reality may be quitedifferent however, because of chipset limitations, etc., thus one cantypically get only a percentage of the theoretical speed. To extend theparty analogy above, if, just when Alice started to talk, a backgroundnoise (e.g., music or TV playing in the background) were turned on soloudly that nothing Alice said could be heard by the host, and as aresult, she basically “wasted” her time-slot, she may have to wait untilher next time-slot to make her point or points, e.g., she may be makingthree conversational points in her time-slot, and if the TV came onafter she made her second point, she may have gotten two of her pointsacross, but not the third in her time-slot. The next time around, shemay get to make her third and final point. Thus, occasionally, Alice mayhave to use multiple time-slots just to get all her points across, ineffect reducing here data-rate. These are effectively failures. Thus,per the limits of this analogy, a CPE, within its time-slot, may send anumber of packets, and some (or all) of these packets may not make itthrough to the AP. This may cause the CPE to have to resend thosepackets, reducing the data rate.

The concept of usage may also be understood by this analogy. Forexample, the percentage of the conversation monopolized by Alice may bethought of as her Usage. One way express this would be to take the totalamount of time Alice spends talking (success and failures), and divedthat by the actual time (e.g., “wall clock time”). However, the analogybecomes more complex if there are a lot of “speakers” (e.g., CPEs). Forexample, in our analogy, if there are 15 speakers (e.g., 14 other peopletalking to the host), you can still get Alice's percentage, but giventhe number of people speaking, the overall percentage may be small. Ifyou're trying to troubleshoot a problem (e.g., Alice, Bob, and Carol areall complaining that the host never seems to hear them because of thebackground TV noise), it would be better to focus on the guests (e.g.,CPEs) of interest. Thus, it may be beneficial to look at Usage for theguests (e.g., CPEs) that are of interest. In the 15 guest example above,the methods and apparatuses described herein may instead calculate thepercentage of time that Alice spent speaking, only looking at the timesspent by Alice, Bob, and Carol. For example, consider that over a 2second interval, guests spoke with the host for the following durations:

TABLE 1 time “talking” in 2 second period “Guest” (CPE) Time talking(msec) Alice 20 Bob 50 Carol 30 David 80 Elsa 40 Famke 90 Gareth 200Hector 90 Indigo 50 Jewel 180 Katrina 200 Mahesh 900 Lewis 20 Nancy 50

From a strictly “wall-clock” usage perspective, Alice's usage was 1%,Bob's was 2.5%, and Carol's was 1.5% in this example. However, if onlyAlice, Bob and Carol are of interest (or have the highest ranking and/orare otherwise selected), they may be examined in more detail by insteadlooking only at usage over the total time this subset of guests (CPEs)were “speaking” with the host (AP). In this case, Alice's airtime usageis 20% (over the total of 0.1 second that they each spoke), Bob'sairtime usage is 50% and Carol's airtime usage is 30%.

A similar analogy may be used to understand the concept of efficiency(or isolated capacity) as described herein. For example, extending theanalogy of the guests speaking at a party even further, it may behelpful to estimate of how impaired communication between Alice and thehost was during the time that the background noise (e.g., when atelevision or radio was playing loudly in the room) by understanding howeffective Alice's speaking would be if she was the only person talking(e.g., excluding the other guests). In term of a CPE communicating withan AP, given that there are some packets that need to be retransmitted,it may be helpful to estimate the maximum rate at which the CPE couldupload data if there was only one CPE. In Alice's case, we already knowhow many failures she has in a given period of time (and conversely, howmany successes). Since we also know what percentage of time Alice wasspeaking, her isolated capacity may be readily calculated. For example,if Alice, Bob, and Carol each get to speak for 10 seconds at a time,over a 300 second interval (e.g., each got to speak 10 times), if Alicesuccessfully spoke 7 times, and the background noise (e.g., a loud TV)was turned on 3 times, Alice was “successful” 70% of the time, i.e.,this was her efficiency (if she was the only person speaking to thehost, the best she would be able to do would be to be successful 70% ofthe time). Similarly, for a CPE, if there are three CPEs, each of whichget to upload data 10 seconds at a time, over a 300 second interval(e.g., each got to upload data 10 times), the first CPE (“Alice”)uploaded data successfully 7 times, and failed to upload data 3 times.So, in this case, the CPE “Alice” has an efficiency of 70% for uploads.For a slightly more realistic example, consider an 802.11g CPE that cantransmit at 54 Mbps. This means that CPE “Alice” may at best, transmitat 40.5 Mbps in this paradigm. Thus, the isolated capacity of CPE“Alice” is 0.7*40.5=28.35 Mbps (since CPE “Alice” was successful only 7out of 10 times). Thus, CPE “Alice” has an upload efficiency in thisexample of 70% and an isolated capacity of 28.35 Mbps. Efficiencyindicates how efficient the CPE (Alice) is at communication, while theisolated capacity indicates a boundary on what a system (e.g., awireless service provider) may expect from a CPE relative to uploadinginformation.

Note that although the general concepts illustrated in this example byanalogy are helpful, they may not be complete. For example, (again byanalogy), guest such as Alice may be talking, and the Host listening,however the host may sometimes talk as well, which may make thissomewhat more complicated. However, it may be useful to assume that thesame characterization made above may be applied to the host as well,including the noise analogy. Thus, wherein upload information (talkingfrom CPE to AP) applies, there may also be a download (e.g., talkingfrom AP to CPE). The upload may be called the Uplink, and the downloadmay be called the Downlink. Thus, if both AP and CPEs (e.g., both Aliceand the host) are communicating, (i.e., the CPE both uploads anddownloads data), a slightly better picture of efficiency may take theaverage of the upload and download efficiencies. For example, CPE“Alice” may have an uploaded efficiency of 70% as discussed above.Similarly, a download efficiency may be determined (e.g., a downloadefficiency from the AP of 82%). Thus, the upload and downloadefficiencies may be averaged to determine Alice's efficiency (e.g., 76%)

This information may be graphically displayed as described above to showefficiency versus air time usage (e.g., the percentage of the time thateach CPE is actually on the air. In our example, the time Alice istalking to the host). In the analogy above, Alice has an efficiency of76% and an air time of 20, Bob has an efficiency of 84% and an air timeof 50, and Carol has an efficiency of 35% and an air time of 30.

A graphical illustration of this may be provided by a TDMA chart such asthat shown in FIG. 16. In general a TDMA window graph may show allclients (CPE's) of an AP and their air time utilization, ordered by theclients' efficiency. The efficiency of the client may be a percentagevalue of the client's current performance relative to the maximumperformance the AP can support, and air time may indicate the amount oftime each of the clients is using on the AP, relative to other clients.The more air time an individual client uses, the less is available forother clients.

Part II: Channel Frequency and Bandwidth Selection Based on Spectral andTraffic Statistics

Also described herein are methods and apparatuses to improvetransmission on between two or more devices (including between an AP andone or more CPEs) in the presence of noise by determining which channelsfrom a variety of potential transmission channels are better thanothers. For example, described herein are methods for, and apparatusesconfigured to, determine a ranking of overall channel quality(“goodness”) for transmission between one or more devices. Theapparatuses and methods described herein may manually or automaticallyuse this determination (ranking) to switch between channels. In somevariations the apparatuses described herein may be configured to performthese rankings at the level of the AP and/or CPEs and/or using a remote(e.g., cloud) server.

A wireless network generally be considered to consist of multipledevices communicating over a single wireless channel. The wirelesschannel may be identified by its center frequency and its bandwidth,i.e. the amount of spectrum it occupies, as illustrated in FIG. 17,showing a schematic example of a channel having a channel centerfrequency (fc) and a bandwidth (bw). Wireless systems may be designed tooperate over a range of channel frequencies and bandwidths. For example,a wireless network can operate over channels with center frequencies5150 MHz, 5155 MHz, 5160 MHz, etc., and bandwidths of 10 MHz, 20 MHz or40 MHz, etc. For one example, all channels in which a wireless channelcan operate may be listed as illustrated in Table 2, below:

TABLE 2 N exemplary channels Channel ID Center Frequency Bandwidthchannel[1] channel[1].fc = 5150 MHz channel[1].bw = 10 MHz channel[2]channel[2].fc = 5150 MHz channel[2].bw = 20 MHz channel[3] channel[3].fc= 5155 MHz channel[3].bw = 10 MHz . . . . . . . . . channel[Nc]channel[Nc]. fc channel[Nc] .bw

The performance of a wireless network including achievable data rates,packet transmission latencies and user experience may be directlyimpacted by interference in the wireless channel, caused by wirelessand/or other electronic devices emitting radio waves in the same oradjacent frequencies occupied by the wireless channel. In the case whena wireless network is operating in an unlicensed frequency band, theoperator of that network may have no control or ownership over thewireless channel and may be required to share its use with otheroperators, under applicable spectral regulations and laws.

Most wireless devices and networks operating in the unlicensed spectrummay have the ability to dynamically change channels. Typically, such achannel change may be triggered by detection of excessive interferenceor presence of, for example, radar signals in the current channel. Thisapproach is inherently reactive and has several drawbacks, including:the performance of the network may have already degraded to a levelwhere connections are dropped etc., before the network is able to detectthat quality of the current wireless channel has, in fact, degraded; andthe network typically selects the new channel based on data collectedover a short time frame. In a longer time frame, this channel's qualitymay also degrade and another channel change is required. The decision tochange from a current channel and the choice of the new channel may bebased on short term observations of interference, which may beinadequate. In particular, in highly dynamic interference scenarios,which are particularly typical in unlicensed frequency bands, thisapproach may be ineffective.

Channel changes, and particularly existing channel channels, may beextremely disruptive to data transmissions and thus reduce theefficiency and usability of the network. Furthermore, for reasonsdescribed above channel change algorithms known in prior art areineffective. Hence, wireless network operators typically disable thisfeature and resort to manually choosing the channels of their network.As it is not feasible for the operator to manually change channels on aregular basis, they typically select a channel at the time ofprovisioning the network or when troubleshooting performance issues. Inaddition to lowering operator productivity, this manual channelselection methodology suffers from the same drawbacks as automatedchannel selection methodologies known in the prior art, highlightedabove.

Ambient Noise Floor and Carrier to Interference and Noise Ratio

In the presence of interference, the goodness/quality of a wirelesschannel can be characterized by the Carrier to Interference and NoiseRatio (CINR), as mentioned above. When represented in decibels, CINR maybe the difference between received signal power and interference plusnoise power. We herein refer to the interference plus noise power levelas the Ambient Noise Floor, as opposed to the Thermal Noise Floor whichis the level of thermal noise power alone. The thermal noise floor isdependent on the receive bandwidth, which is generally static. On theother hand, the ambient noise floor varies significantly with time as itis dependent on interference signal levels, as shown in FIG. 18.

Methods and Apparatuses for Grading/Ranking Channels

In general, described herein are methods and apparatuses for rankingchannels (in some variations including any used channel currently beingused by the device(s), in other variations including channels not beingused by the device(s)) based on a determination of channel “goodness”calculated from an indication of the historical and/or instantaneous(including a time-specific indication) of power (noise, such as theambient noise floor) for each channel, and in some variations one ormore indicators of the capability of one or more stations (e.g., CPEslinked to an AP) specific to that channel. For example, described hereinare methods and apparatuses to determine the best channel or a list ofbest channels to operate a wireless network based on statisticalinformation or radio and data traffic, collected over a (e.g., long,greater than about 12 hr, greater than about 24 hour, greater than about36 hour, greater than about 48 hours, etc.) time period.

These methods and apparatuses for performing them may, for example,provide a table ranking or listing of channels available to network ofAPs and CPEs for communication between the two. The listing/array/tablemay be one-dimensional and unqualified (e.g., simply listing as best toworst, or more/less “good”, etc.), or the listing/array/table may beone-dimensional and qualified (e.g., indicating which CPEs in thenetwork would be best/worst for this channel, etc.). In some variationsthe listing/array/table is multi-dimensional and qualified orunqualified, e.g., including a vector that has individual rankings forall or a sub-set of the CPEs in the network.

An apparatus (generally including device and systems) configured tograde/rank channels as described herein may generally include a spectrumanalyzer that is adapted specifically to monitor activity on otherchannels in the network (e.g., concurrent with transmitting/receivingactivity in an in-use channel). For example, any of the devicesdescribed herein configured to rank or grade channels, or from part of anetwork that ranks/grades channels, may include a radio having a firstpath with a transmitter/receiver (or transceiver) that operates on achannel and may be changed (tuned) to another channel. The apparatus mayinclude a second (in some variations parallel) path that includes aspectrum analyzer for monitoring energy on the frequency spectrum(including or excluding the frequencies currently being used by theradio to transmit/receive). The apparatus may store this information asa matrix of frequency, time and energy (e.g., the energy reading at aparticular frequency at time of day). Additionally or alternatively,this information may be transmitted to a remote server and any of theapparatuses described herein may access this matrix in determining theparameters (e.g., ambient noise floor) as described herein.

Using Achievable Data Rate at Channel Quality Metric

In one variation, the goodness of a channel may be determined by anestimated achievable data rate of that channel, which may be specific toindividual stations in the network and may therefore be determinedseparately, or in some variations collectively, for each station. Theachievable data rate may be determined by first estimating the ambientnoise floor of that channel and then translating it to an achievabledata rate, as illustrated schematically in FIG. 19. As shown in thisexample, given the received signal strength (rx_power), the CINR forthat channel (channel[i].CINR) may be determined by subtractingchannel[i].ambient_NF from rxpower. The channel[i].achievable_dataratemay be computed, for example, from this channel[i].CINR by using alook-up table (LUT_RATE) of values that can be empirically ortheoretically determined and may be specific to a device or class ofdevices. For example, the look up table (LUT_RATE), may includeregulatory rules for EIRP in determining the achievable data rate.

In another variation, the goodness (which may be expressed in Kbps/Mbps)of a channel may be measured by the estimated average achievable datarate of that channel, where ambient noise floor values measured atdifferent time periods (and received, for example, from the spectrumanalyzer information described above), may be considered in determiningthe weighted average achievable data rate. The ambient noise floor maybe measured at time instant j, and the channel[i].ambient_NF[j] may beconverted to an estimated achievable data ratechannel[i].achievable_datarate[j] for that period. The averageachievable data rate may be determined by averagingchannel_[i].achievable_datarate[j] after weighting by a factor weight[j]values as illustrated in FIG. 20. Weighting factors may be based oninformation specific to the station (CPE and/or AP).

For example, in some variations, weighting factors may be based onreceive usage. In some variations, channel usage in the receivedirection may be used to compute the weighting factors. The channelreceive usage at time instant j may be given by channel_usage[j] withvalue between 0 and 1 indicating wireless channel receive usage of thenetwork at time j, where 0 indicates no usage and 1 indicates maximumusage. Weight [j] may be computed as follows: Weight[j]=(channel usage[j])/(channel usage [1]+channel usage[2]+ . . . +channel usage [j])

Any of the variations described above may be used with specificend-point devices of point-to-point connections (e.g., AP to singleCPE), an may also be adapted for use with point-to-multipoint(AP-multiple CPEs).

For example, for a point-to-point (PTP) wireless link, the apparatus ormethod implemented by the apparatus(s) may consider informationavailable from both ends (e.g., master and slave, AP and CPE, etc.) ofthe link to determine the best channel. Similarly, for apoint-to-multipoint (PMP) network, the apparatus and method may considermultiple end-points/subscriber modules (SMs) and the access-point (AP)to determine the best channel.

For example, an SMs (in the case of PMP) and the slave device (in thecase of PTP) may periodically send a “spectrum information” packet tothe AP/master. For the this example, we may refer to SMs/PTPSLAVES andthe AP as a Connected Device (CD). FIG. 21 shows one example of thepacket (Spectrum information packet) that may be transmitted between thedevices (e.g., from the slave/CPE stations to the AP). In this example,the packet indicates the number of channels and periods (Nc, Np) andlists the receive usage information each Np period (“channel_rx_usage[ .. . ]”) as well as the frequency (fw), bandwidth (bw) and ambient noisefloor for each channel, as illustrated.

In some variations, a connected device can be considered as a 4-tuple,e.g.: (mac-address, priority, channel_rx_usage[0 . . . Np−1],spectrum_info[0 . . . Nc−1]). In this example, channel_rx_usage is avector containing channel receive usage information for Np periods, andspectrum_info is a vector containing information for Nc channels.

Each spectrum information channel can be considered as a 3-tuple, e.g.:(fc, bw, ambient_NF[0 . . . Np−1], goodness), where ambient NF is avector containing ambient noise floor information for Np periods, andgoodness is computed by using the channel receive usage as weights foreach of Np periods. This information may include priority whendetermining the grading/ranking. For example, see FIG. 22. In general,the AP/PTPMASTER's connected device entity may have the highestpriority.

Thus, in general, each device may include multi-dimensional informationfor each channel (or range of frequencies in the channel) in amultiple-device network (e.g., point-to-multipoint network). Theapparatuses and methods described herein may simplify thismulti-dimensional information into a single dimension. For example, whena channel includes multiple different frequencies, the noise information(Ambient Noise) used to calculate the goodness may be the maximum (e.g.,worst case scenario) from all of the frequencies in the channel, or itmay be an average, median, etc. In addition, a subset of timing rangesmay be chosen, e.g., using a range of time (going backwards from theinstant/current time a particular value, such as 1 hr, 2 hrs, 3 hrs, 4hrs, 12 hrs, 24 hrs, etc. or any increment thereof), or only the mostrecent time values may be chosen (e.g., and selected from the matrix ofenergy provided by the spectral information).

Thus, the apparatuses and methods described herein may determine aranking/scoring and/or listing of the top N channels for a network foreach bandwidth. For example, Nb may be set as the number of availablebandwidth options. e.g. (10, 20, 30, 40, 50, 60, 80 MHz) and Nd as thenumber of connected devices. The apparatuses and methods describedherein may split the SpectrumInfo vector by bandwidth, and initialize aPerBandWidth (PBW) entity for each bandwidth k=0 . . . Nb−1. This may bedetermined by the equation shown below (and in FIG. 22A):

${{{PBW}\lbrack k\rbrack}.{{goodness}\lbrack j\rbrack}} = \frac{\sum\limits_{0}^{{Nd} - 1}{{{{CD}\lbrack i\rbrack}.{{SpectrumInfo}\lbrack j\rbrack}.{goodness}} \times {{{CD}\lbrack i\rbrack}.{Priority}}}}{\sum\limits_{0}^{{Nd} - 1}{{{CD}\lbrack i\rbrack}.{Priority}}}$

Where, for each j, where PBW[k].bw=CD[i].SpectrumInfo[j].bw and wherej=0 . . . Nc−1, i=0 . . . Nd−1, k=0 . . . Nb−1. Sorting PBW[k].goodnessin descending order and using the top N channels may provide the bestfrequencies for each available bandwidth option. The bps-per-Hz metricused herein also provides a normalized way to judge spectral usage andefficiency and for a given channel. For example, this metric may be aratio of the PBW[k].goodness[j] and PBW[k].bw (e.g.,PBW[k].goodness_[j]/PBW_[k].bw).

For example table 3, below, shows an example of top-3 channels, with thecomputed goodness and the bps-per-Hz:

TABLE 3 exemplary ranking of bands Frequency 10 MHz 20 MHz 40 MHz 80 MHz5785 62 (6.2 bps/Hz) 120 (6.0 bps/Hz) 150 (3.75 bps/Hz) 250 (3.12bps/Hz) 5200 50 (5.0 bps/Hz) 80 (4.0 bps/Hz) 120 (3 bps/Hz) 180 (2.25bps/Hz) 5500 70 (7.0 bps.Hz) 100 (5.0 bps/Hz) 90 (2.25 bps/Hz) 75 (0.875bps/Hz)

In general, and operator using the apparatuses described herein canselect the desired frequency, either based on absolute capacity requiredfor that network, or the operator can optimize the network for spectralefficiency based on the computed bps/Hz. As an example: with a 80 MHzchannel centered at 5785 MHz, the operator may get a capacity of 250Mbps, but it comes at a lower spectral efficiency. Dividing this networkinto three RF domains (sectors), and using 20 MHz channels centered at5785, 5200 and 5500 MHz may provide a total of 300 Mbps capacity using60 MHz of total spectrum.

In operation, any of the apparatuses described herein may be used toprovide information for automatic or manual switching between channels.For example, in automatic switching, a master device (e.g., AP) maydetermine that it is time to switch based on any appropriate criterion,such as overall degradation of signal transmission quality, ordegradation of transmission quality with one or more high-prioritydevices. For example, when a quality threshold is passed. Thisdetermination may be made locally (at the AP and/or CPEs) or remotely(e.g., in a cloud configuration) or both. Alternatively a user(administrator) may determine that the quality has degraded and maymanually determine to switch channels. In either case, the apparatusesmay apply the methods described herein to determine which one or morechannels provide the best options for switching. In an automaticconfiguration, the system may switch to the top ranking channel, or mayuse a selection of the top ranked channels to compare with other factors(including nearby networks or other APs to determine what the switchingshould be). In manual configurations the system may present the user(administrator) with the channel options in a simple list (annotated orunannotated, as described above) so that the user may make the bestdecision possible in choosing the band to switch to.

For example, described herein are apparatuses including a processor thatholds or receives any of the information described herein and displaysthe ranking/grading/listing as described herein, and allows a user toselect from among the listed/graded/scored bands which frequency band tochange to. The apparatus may include software, hardware, firmware of thelike, and is dependent upon connection to and/or receiving theinformation described herein (e.g., spectral information) from one ormore stations in the network (and preferably all of the stations).

Optimization of Channel Selection

Any of the methods and apparatuses described herein may be configured tooptimize channel selection and either present one or more “top” rankedchannels to a user or automatically switch to the top ranked channel, bydetermining a ranking of frequency channels within a target frequencyrange by spectral efficiency. Described herein are methods of performingthis optimization as well as apparatuses configured to perform thesemethods. These apparatuses are typically access point devices (thoughnot limited to such devices). These devices may operate inpoint-to-point (PTP) or point-to-multipoint (PTMP) configurations, andmay optimize in both. Any of these apparatuses (e.g., APs) may include avisual tool allowing user interaction, including display of the top(optimized) frequency channels, display of the frequency spectralinformation for devices communicating with the AP and/or the AP spectralfrequency information, as well as selection of the channel bandwidth,the frequency range to be optimized over, etc.

For example, an apparatus such as an access point may be configured toestimate the capacity for all or some of the devices communicating withthe AP from the usage data (e.g., signal strength data, including RSSI).The usage data for each link (e.g., between the AP and the clientdevices) may allow the apparatus to estimate the capacity based on thereceived signal strength and to determine the capacity at both ends ofeach link, which may then be used to determine spectral efficiency.

An apparatus, such as an access point, may be configured to implement amethod of optimizing channel selection, as described herein. Forexample, an access point (AP) may be configured to optimize the Tx/Rxchannel and/or channel width based (either automatically or manually),by determining the received signal strength at both ends of the linkbetween the AP and a client (e.g., a CPE) that is wirelesslycommunicating with the AP. As described below, the apparatus may beconfigured to do this for every client that is connected to the AP, orjust for a subset of the clients connected to the AP, such as the top tonumber of clients, e.g., the top twenty (tn=20) clients using the mostbandwidth in a given time period. In addition, the AP may use thehistorical spectral data, which gives the energy in the band from othersources, including interferers, for the previous predetermined timeperiod (e.g., 24 hours, 7 days, etc.), and using the Tx and Rx signalstrength (usage data), as well as the historical spectral data, thecapacity of the link can be estimated. In estimating the capacity of thelink, the worst case capacity may be determined, or an average capacitymay be determined, or both, from all (or the subset of) clientcommunicating with the AP.

For example, the signal strength and interference may be used, asdescribed above, to determine a channel capacity based on the signal tointerference plus noise (SINR). For example, a lookup table may be usedto calculate the data rate based on the signal strength and spectraldata for each client. In practice, each client type (e.g., CPE devicetype) may have a slightly different lookup table for each product; insome variations a generic look-up table may be used. Thus, the signalstrength and spectral information may be used to determine a data rate(e.g., per length) for each client (CPE). The method or apparatus may beconfigured to look at the clients with the most usage (e.g., the top toclients based on usage), and either average the data rate per length, oruse some other adjusted data rate (e.g., a weighted average, a mean,median, etc.). This may provide an average or consolidated data rate forthe AP and its clients, and this data rate is then typically divided bythe amount of spectrum used (the channel width), such as for example, 10MHz, 20 MHz, 40 MHz, 50 MHz, 60 MHz, 80 MHz, etc.) to give a spectralefficiency for each channel at a particular channel width (bandwidth),in bits per second per Hz. (Bps/Hz). Channels may thus be ranked byspectral efficiency. Any of the apparatuses described herein maytherefore be configured to display the ranking, e.g., by listing,labeling, or otherwise showing the top (e.g., the top one, two three,four, five, etc.) channels with the highest spectral efficiencies at aparticular and/or predetermined channel width.

For example, FIG. 23 illustrates one example of a method of determiningspectral efficiency rankings for each of a plurality of frequencychannels. For example, initially (and optionally) a method ofdetermining spectral efficiency rankings may collect historicalfrequency spectral information for one or more devices linked to anaccess point (AP). This information may be collected, stored, or held,in the AP 2301. Usage data may also be collected, stored and/or held inthe AP. For example, usage data (e.g., signal strength) for the one ormore devices linked to AP may be collected in the AP 2303. Thereafter,at each of a plurality of channel frequencies, an interference plusnoise (SINR) may be determined for each of the one or more devices 2305,and a data rate may be determined from the SINR and historical frequencyspectral information specific to each of the one or more devices at eachof the one channel frequencies. Once the data rates have been determined(as described above, this may be achieved by using a look-up table thatis specific to each type of device) for each device, an aggregate datarate may be determined for the network; the aggregate data rate may be afunction of all or a subset of the devices (e.g., average, mean, median,weighted average, maximum, minimum, etc.) 2307. An aggregate data ratemay be determined at each frequency channel to be examined. For example,the frequency range may be divided up into a predetermined number ofchannels (e.g., between 5 and 1000 channels, 5 and 500 channels, etc. achannel every 1 kHz, etc.) and a spectral efficiency determined for eachchannel.

The aggregate data rate at each frequency may then be divided by thechannel width to determine the spectral efficiency at that frequency2309. The resulting set of channels and spectral efficiencies may thenbe stored. In some variations (as illustrated in FIG. 23), the steps maybe performed iteratively, e.g., by sequentially determining the spectralefficiency at different frequencies and repeating the process atdifferent frequencies. Alternatively, this procedure may be performed inparallel for different frequencies, or some combination of parallel andsequential, until a spectral efficiency has been determined for all ofthe frequency channels within the frequency range 2311.

An apparatus, such as an access point device, may be configured tooptimize the channel selection using a method such as that describedabove. For example, FIG. 33 illustrates one example of an access point3300 that is wirelessly communicating with a plurality of other devices(e.g., stations, CPEs, etc.) 3350, 3350′. In this example, only twoother devices 3350, 3350′ are shown, however additional devices may bepart of the network as well. The access point 3350 typically includes anantenna 3301, wireless radio circuitry (e.g., transceiver) 3303, and acontroller that may include a processor, memory, and the like, includingan output 3309 (e.g., a user interface, as described herein) forcontrolling operation of the access point. The control may be configuredspecifically to perform any of the methods described herein, includingthe optimization of the frequency channel. Each of the client devices(stations, CPEs, etc.) 3350, 3350′ may typically include a wirelessantenna 3351 and radio circuit 3353, which may be separated orintegrated with a controller/processor 3355′. These devices may alsoeach include a second receiver 3358 that is configured as a spectrummonitor for monitoring the frequency spectrum. In some variation, thisspectrum monitor is not separate from the transceiver of the radiofrequency, but instead the apparatus is configured to monitor thespectrum when not otherwise receiving or transmitting. Note thatalthough FIG. 33 is described herein in reference to an apparatusconfigured to optimize frequency channel, this illustration of awireless network may be relevant to any of the apparatuses and methodsdescribed herein, including in particular, method and apparatuses orproviding a ranked indicator of station efficiency and/or methods andapparatuses for monitoring a wireless network including transmitting aplurality of sounding packets and determining EVM information.

In general, an apparatus of optimizing the frequency channel of anaccess point, and therefore of the network, may generally include acontroller that is configured to generate a tool such as the tool shownin FIGS. 24B and 24C. For example, FIG. 24A illustrates a user interfacefor an access point that is communicating with one or more stations(e.g., CPEs), describing features and characteristics of the accesspoint, the number of connections, and a graphical description of one ormore link between the access point a station. In this example, the userinterface includes a pair of constellation diagrams 2401, 2403 that maybe generated as described above. This user interface (as well as anyassociated tools, such as the tool 2410 shown in FIGS. 24B and 24C thatmay allow optimization as described herein.

In FIG. 24B, the tools is a portion of the user interface that acts as apop-up window 2410 that includes a visual indicator (e.g., chart, table,bar) of the frequency range, as well as indicating the frequencyspectral information for the AP and each (or some) of the deviceswirelessly connected with the AP 2423. In FIG. 24C, this is indicated bythe horizontal rows (labeled on the far right side of the tool) that arelabeled as heat maps indicating the energy at each point of the spectrumas measured over some time period (e.g., the last 24 hours, 48 hours, 3days, 4 days . . . etc.). A key to this heat mapping is shown in theupper right 2419. The x-axis in this example is frequency, and thefrequency range is shown along the bottom. Sliders may be used to adjustthe upper 2455′ and lower 2455 ends of the frequency range analyzed.

The user interface tool 2410 may also include a listing of recommendedchannel widths (bandwidths) 2415, as illustrated on the far left side ofthe tool. The recommended channel widths may include predicted spectralefficiencies and capacities for each of the different channel widths(e.g., 10, 20, 30, 40, 60, 80 MHz). Any of these channel widths may beselected (e.g., by clicking on them) using this portion of the tooland/or by using a control such as the slider 2417 in the upper middle ofthe tool.

In general, the access point may be configured to provide this tooleither directly (e.g., by hosting a webpage that a user may access) orindirectly, by transmitting the information to a third partycontroller/server that may communicate with the access point and theuser.

In FIGS. 24B and 24C, the tool also shows the optimized (e.g., topranked) frequency channels determined by the methods described above atthe selected bandwidth (e.g., 40 MHz in FIGS. 24B and 24C). In thisexample, the three channels having the highest spectral efficiency areshown in boxes above the graph of the spectral information 2420, 2420′,2420″. In this example, the channels having the best spectral efficiencyare 5230 GHz 2420, which has a spectral efficiency of 4.6 Bps/Hz (bitsper second per Hz), 5380 GHz 2420′ which also has a spectral efficiencyof 4.6 Bps/Hz (bits per second per Hz), and 5580 GHz 2420″, which has aspectral efficiency of 4.8 Bps/Hz (bits per second per Hz). The toolalso allows the user to manually select a frequency and spectralefficiency is of the selected frequency is also shown at the top, andthe historic spectral information is highlighted 2430. In this example,the gray boxes illustrate the top three recommended channels.

In this example, as mentioned above, the channel width is manuallydetermined, however in some variations it may be automatically selected(or suggested). For example, the channel width may be optimized. Thecapacity for the network may be determined based on, for example, thetraffic through the Ethernet port. Thus, the access point may determinehow much capacity is needed to send data to each device. For example, ifthe access point needs only 100 Mbps per second, then, as shown in therecommended channel widths 2415 portion, the channel width maybe thesmallest capacity to meet this requirement, e.g., 20 MHz in FIG. 24C.

As mentioned above, the user interface tool which may form part of theapparatus (e.g., an access point apparatus) may also allow manipulationof the optimization to determine channel frequency. In FIG. 25, the toolis shown without any optimization, though a heat map of the frequencyspectral information for the access point and each of 20 connected unitsare shown. In this example, the 20 connected devices may be a subset ofthe total number of selected device; for example they may represent onlythe 20 highest-ranked devices for station efficiency, average airtime.The user may select any channel frequency by clicking on it, as shown.

FIG. 26 illustrates the selection of the channel width (in this example,20 MHz) by clicking on the 20 MHz option in the recommended channelwindows. Once the channel width is set, the apparatus may determine thetop channel efficiencies and indicate them as described above and shownagain in FIG. 26. In this example, the three most spectrally efficientchannels are 5380 (7.2 Bps/Hz), 5170 (7.1 Bps/Hz) and 5790 (6.8 Bps/Hz).

FIG. 27 illustrates the selection of a different channel width (e.g., 60MHz), which results in different top spectrally efficient channels(e.g., 5590, with 7.5 Bps/Hz, 5250, with 6.9 Bps/Hz, and 5390, with 6.4Bps/Hz). As mentioned above, the frequency range over which theoptimization is performed may also be modified, as shown in FIG. 28, inwhich the sliders at the bottom of the frequency range may be adjustedto narrow or expand the frequency range.

FIGS. 24-28 illustrate the tool for an access point that is configuredas a point to multipoint (PTMP) device. These apparatuses, tools andmethods may also be used with point to point (PTP) devices, as shown inFIG. 29. In this example, the access point device may be insteadconfigured as a PTP device and the local and remote devices propertiesmay be displayed, including a local frequency spectral information shownas actual spectrograms. The remote device spectrogram is shown on thebottom and the local on the top. Again, a heat map may indicate theprobability of the frequency having an energy level as shown by the line(which may be an average energy level, or some other metric for thatfrequency). The tool is otherwise the same, and functions as describedabove. For example, as shown in FIG. 30, a 20 MHz channel bandwidth maybe selected, and the resulting top three spectral efficiencies may bedetermined (e.g., 5810, with 7.2 Bps/Hz; 5220, with 7.1 Bps/Hz; and 5760with 6.8 Bps/Hz). FIG. 31 shows the shift to a different channelbandwidth (e.g., 30 MHz) and the resulting shift in the highest spectralefficiencies. Similarly, FIG. 32 illustrates the selection of a narrowerrange of frequencies to optimize over.

When a feature or element is herein referred to as being “on” anotherfeature or element, it can be directly on the other feature or elementor intervening features and/or elements may also be present. Incontrast, when a feature or element is referred to as being “directlyon” another feature or element, there are no intervening features orelements present. It will also be understood that, when a feature orelement is referred to as being “connected”, “attached” or “coupled” toanother feature or element, it can be directly connected, attached orcoupled to the other feature or element or intervening features orelements may be present. In contrast, when a feature or element isreferred to as being “directly connected”, “directly attached” or“directly coupled” to another feature or element, there are nointervening features or elements present. Although described or shownwith respect to one embodiment, the features and elements so describedor shown can apply to other embodiments. It will also be appreciated bythose of skill in the art that references to a structure or feature thatis disposed “adjacent” another feature may have portions that overlap orunderlie the adjacent feature.

Terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the invention.For example, as used herein, the singular forms “a”, “an” and “the” areintended to include the plural forms as well, unless the context clearlyindicates otherwise. It will be further understood that the terms“comprises” and/or “comprising,” when used in this specification,specify the presence of stated features, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, steps, operations, elements, components, and/orgroups thereof. As used herein, the term “and/or” includes any and allcombinations of one or more of the associated listed items and may beabbreviated as “/”.

Spatially relative terms, such as “under”, “below”, “lower”, “over”,“upper” and the like, may be used herein for ease of description todescribe one element or feature's relationship to another element(s) orfeature(s) as illustrated in the figures. It will be understood that thespatially relative terms are intended to encompass differentorientations of the device in use or operation in addition to theorientation depicted in the figures. For example, if a device in thefigures is inverted, elements described as “under” or “beneath” otherelements or features would then be oriented “over” the other elements orfeatures. Thus, the exemplary term “under” can encompass both anorientation of over and under. The device may be otherwise oriented(rotated 90 degrees or at other orientations) and the spatially relativedescriptors used herein interpreted accordingly. Similarly, the terms“upwardly”, “downwardly”, “vertical”, “horizontal” and the like are usedherein for the purpose of explanation only unless specifically indicatedotherwise.

Although the terms “first” and “second” may be used herein to describevarious features/elements (including steps), these features/elementsshould not be limited by these terms, unless the context indicatesotherwise. These terms may be used to distinguish one feature/elementfrom another feature/element. Thus, a first feature/element discussedbelow could be termed a second feature/element, and similarly, a secondfeature/element discussed below could be termed a first feature/elementwithout departing from the teachings of the present invention.

As used herein in the specification and claims, including as used in theexamples and unless otherwise expressly specified, all numbers may beread as if prefaced by the word “about” or “approximately,” even if theterm does not expressly appear. The phrase “about” or “approximately”may be used when describing magnitude and/or position to indicate thatthe value and/or position described is within a reasonable expectedrange of values and/or positions. For example, a numeric value may havea value that is +/−0.1% of the stated value (or range of values), +/−1%of the stated value (or range of values), +/−2% of the stated value (orrange of values), +/−5% of the stated value (or range of values), +/−10%of the stated value (or range of values), etc. Any numerical rangerecited herein is intended to include all sub-ranges subsumed therein.

Although various illustrative embodiments are described above, any of anumber of changes may be made to various embodiments without departingfrom the scope of the invention as described by the claims. For example,the order in which various described method steps are performed mayoften be changed in alternative embodiments, and in other alternativeembodiments one or more method steps may be skipped altogether. Optionalfeatures of various device and system embodiments may be included insome embodiments and not in others. Therefore, the foregoing descriptionis provided primarily for exemplary purposes and should not beinterpreted to limit the scope of the invention as it is set forth inthe claims.

The examples and illustrations included herein show, by way ofillustration and not of limitation, specific embodiments in which thesubject matter may be practiced. As mentioned, other embodiments may beutilized and derived there from, such that structural and logicalsubstitutions and changes may be made without departing from the scopeof this disclosure. Such embodiments of the inventive subject matter maybe referred to herein individually or collectively by the term“invention” merely for convenience and without intending to voluntarilylimit the scope of this application to any single invention or inventiveconcept, if more than one is, in fact, disclosed. Thus, althoughspecific embodiments have been illustrated and described herein, anyarrangement calculated to achieve the same purpose may be substitutedfor the specific embodiments shown. This disclosure is intended to coverany and all adaptations or variations of various embodiments.Combinations of the above embodiments, and other embodiments notspecifically described herein, will be apparent to those of skill in theart upon reviewing the above description.

What is claimed is:
 1. A method of monitoring a wireless network, themethod comprising: establishing link between a first radio device and asecond radio device; periodically transmitting a plurality of soundingpackets from the first radio device, wherein each of the plurality ofsounding packets are transmitted in a different modulation type;receiving at least some of the plurality of sounding packets at thesecond radio device; determining estimated error vector magnitude (EVM)information based on a carrier-to-interference noise ratio from thereceived at least some of the plurality of sounding packets; aggregatingthe determined estimated error vector magnitude information for apredetermined period of time; and displaying an animated constellationdiagram by generating pseudo-EVM data points based on the aggregatedestimated error vector magnitude information, wherein the pseudo-EVMdata points are determined within a standard deviation of the estimatederror vector magnitude information.
 2. A method of monitoring a wirelessnetwork, the method comprising: transmitting a plurality of soundingpackets from a first radio device, wherein each of the plurality ofsounding packets are transmitted in a different modulation type;receiving at least some of the plurality of sounding packets at a secondradio device; determining estimated error vector magnitude (estimatedEVM) information based on a carrier-to-interference noise ratio from thereceived at least some of the plurality of sounding packets; anddisplaying an animated constellation diagram by generating pseudo-EVMdata points based on the estimated EVM information, wherein thepseudo-EVM data points are determined within a standard deviation of theestimated error vector magnitude information.
 3. The method of claim 2,wherein transmitting the plurality of sounding packets from the firstradio device comprises transmitting 3 or more sounding packets, whereineach of the three or more sounding packets are transmitted in adifferent modulation type.
 4. The method of claim 2, further comprisingselecting the modulation type of the constellation diagram based on thereceived sounding packets.
 5. The method of claim 2, whereintransmitting the plurality of sounding packets from the first radiodevice comprises transmitting 3 or more sounding packets, wherein eachof the three or more sounding packets are transmitted in a differentmodulation type selected from the group consisting of: BPSK, QPSK,16QAM, 64QAM, 256QAM and 1024QAM.
 6. The method of claim 2, whereintransmitting the plurality of sounding packets from the first radiodevice comprises repeatedly and sequentially transmitting soundingpatents in each of three of more different modulation types.
 7. Themethod of claim 2, wherein each sounding packet encodes estimated errorvector magnitude (estimated EVM) information.
 8. The method of claim 2,wherein determining estimated error vector magnitude (estimated EVM)information from the received at least some of the plurality of soundingpackets comprises selecting the estimated error vector magnitudeinformation from the received at least some of the plurality of soundingpackets based on the highest-order modulation type received by thesecond radio device.
 9. The method of claim 2, wherein displaying one orboth of the constellation diagram and the histogram based on theestimated error vector magnitude information comprises displaying boththe constellation diagram and the histogram.
 10. The method of claim 2wherein displaying an animated constellation diagram by generatingpseudo-EVM data points comprises updating the constellation diagram bygenerating new pseudo-EVM data points based on the estimated EVMinformation before determining new estimated EVM information fromreceived at least some of the plurality of sounding packets.
 11. Themethod of claim 2, wherein transmitting the plurality of soundingpackets from the first radio device comprises transmitting 3 soundingpatents comprising BPSK, 16QAM, and 256QAM.
 12. A wireless deviceconfigured to optimize modulation type when wirelessly communicating,the device comprising: a wireless radio; an antenna; and a controllercoupled to the wireless radio and configured to receive a plurality ofsounding packets wherein at least some of the sounding packets have beenmodulated with different modulation types, wherein the controller isconfigured to determine an estimated error vector magnitude (estimatedEVM) information based on a carrier-to-interference noise ratio from thereceived at least some of the plurality of sounding packets, wherein thecontroller is further configured to generate an animated constellationdiagram by generating pseudo-EVM data points based on the estimated EVMinformation and updating the constellation diagram by generating newpseudo-EVM data points based on the estimated EVM information beforedetermining new estimated EVM information from received at least some ofthe plurality of sounding packets; and an output coupled to thecontroller and configured to output the animated constellation diagram.13. The device of claim 12, wherein the controller is further configuredto transmit a second plurality of sounding packets from the wirelessradio and antenna, wherein at least some of the sounding packets of thesecond plurality of sounding packets are transmitted in differentmodulation types.
 14. The device of claim 12, wherein the controller isconfigured to receive at least three or more sounding packets, whereineach of the three or more sounding packets are transmitted in adifferent modulation type.
 15. The device of claim 12, wherein thecontroller is configured to receive the plurality of sounding packets,wherein the sounding packets are transmitted in different modulationtypes selected from the group consisting of: BPSK, QPSK, 16QAM, 64QAM,256QAM and 1024QAM.
 16. The device of claim 12, wherein the controlleris configured to receive the plurality of sounding packets that arerepeatedly and sequentially transmitted in each of three of moredifferent modulation types.
 17. The device of claim 12, wherein thecontroller is configured to receive sounding packets that encodeestimated EVM information.
 18. The device of claim 12, wherein thecontroller is configured to determine estimated EVM information from thereceived plurality of sounding packets by selecting estimated EVMinformation from the received sounding packets based on thehighest-order modulation type received by the device.
 19. The device ofclaim 12, wherein the controller is configured to output both of theconstellation diagram and the histogram.
 20. The device of claim 12,wherein the controller is further configured to output the animatedconstellation diagram wherein the pseudo-EVM data points are within astandard deviation of the estimated error vector magnitude information.